/************************************************************** * * Licensed to the Apache Software Foundation (ASF) under one * or more contributor license agreements. See the NOTICE file * distributed with this work for additional information * regarding copyright ownership. The ASF licenses this file * to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance * with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. * *************************************************************/ // MARKER(update_precomp.py): autogen include statement, do not remove #include "precompiled_svx.hxx" #include "ChildrenManagerImpl.hxx" #include #include #ifndef _COM_SUN_STAR_ACCESSIBLE_ACCESSIBLESTATETYPE_HPP_ #include #endif #include #include #include #include #include #include using namespace ::com::sun::star; using namespace ::com::sun::star::accessibility; using ::com::sun::star::uno::Reference; namespace accessibility { namespace { void adjustIndexInParentOfShapes(ChildDescriptorListType& _rList) { ChildDescriptorListType::iterator aEnd = _rList.end(); sal_Int32 i=0; for ( ChildDescriptorListType::iterator aIter = _rList.begin(); aIter != aEnd; ++aIter,++i) aIter->setIndexAtAccessibleShape(i); } } //===== AccessibleChildrenManager =========================================== ChildrenManagerImpl::ChildrenManagerImpl ( const uno::Reference& rxParent, const uno::Reference& rxShapeList, const AccessibleShapeTreeInfo& rShapeTreeInfo, AccessibleContextBase& rContext) : ::cppu::WeakComponentImplHelper2< ::com::sun::star::document::XEventListener, ::com::sun::star::view::XSelectionChangeListener>(maMutex), mxShapeList (rxShapeList), mxParent (rxParent), maShapeTreeInfo (rShapeTreeInfo), mrContext (rContext), mnNewNameIndex(1), mpFocusedShape(NULL) { } ChildrenManagerImpl::~ChildrenManagerImpl (void) { DBG_ASSERT (rBHelper.bDisposed || rBHelper.bInDispose, "~AccessibleDrawDocumentView: object has not been disposed"); } void ChildrenManagerImpl::Init (void) { // Register as view::XSelectionChangeListener. Reference xController(maShapeTreeInfo.GetController()); Reference xSelectionSupplier ( xController, uno::UNO_QUERY); if (xSelectionSupplier.is()) { xController->addEventListener( static_cast(this)); xSelectionSupplier->addSelectionChangeListener ( static_cast(this)); } // Register at model as document::XEventListener. if (maShapeTreeInfo.GetModelBroadcaster().is()) maShapeTreeInfo.GetModelBroadcaster()->addEventListener ( static_cast(this)); } long ChildrenManagerImpl::GetChildCount (void) const throw () { return maVisibleChildren.size(); } /** Return the requested accessible child object. Create it if it is not yet in the cache. */ uno::Reference ChildrenManagerImpl::GetChild (long nIndex) throw (::com::sun::star::uno::RuntimeException, ::com::sun::star::lang::IndexOutOfBoundsException) { // Check wether the given index is valid. if (nIndex < 0 || (unsigned long)nIndex >= maVisibleChildren.size()) throw lang::IndexOutOfBoundsException ( ::rtl::OUString::createFromAscii( "no accessible child with index ") + nIndex, mxParent); return GetChild (maVisibleChildren[nIndex],nIndex); } /** Return the requested accessible child object. Create it if it is not yet in the cache. */ uno::Reference ChildrenManagerImpl::GetChild (ChildDescriptor& rChildDescriptor,sal_Int32 _nIndex) throw (::com::sun::star::uno::RuntimeException) { if ( ! rChildDescriptor.mxAccessibleShape.is()) { ::osl::MutexGuard aGuard (maMutex); // Make sure that the requested accessible object has not been // created while locking the global mutex. if ( ! rChildDescriptor.mxAccessibleShape.is()) { AccessibleShapeInfo aShapeInfo( rChildDescriptor.mxShape, mxParent, this, mnNewNameIndex++); // Create accessible object that corresponds to the descriptor's // shape. AccessibleShape* pShape = ShapeTypeHandler::Instance().CreateAccessibleObject ( aShapeInfo, maShapeTreeInfo); rChildDescriptor.mxAccessibleShape = uno::Reference ( static_cast(pShape), uno::UNO_QUERY); // Now that there is a reference to the new accessible shape we // can safely call its Init() method. if ( pShape != NULL ) { pShape->Init(); pShape->setIndexInParent(_nIndex); } } } return rChildDescriptor.mxAccessibleShape; } uno::Reference ChildrenManagerImpl::GetChild (const uno::Reference& xShape) throw (uno::RuntimeException) { ChildDescriptorListType::iterator I, aEnd = maVisibleChildren.end(); for (I = maVisibleChildren.begin(); I != aEnd; ++I) { if ( I->mxShape.get() == xShape.get() ) return I->mxAccessibleShape; } return uno::Reference (); } /** Find all shapes among the specified shapes that lie fully or partially inside the visible area. Put those shapes into the cleared cache. The corresponding accessible objects will be created on demand. At the moment, first all accessible objects are removed from the cache and the appropriate listeners are informed of this. Next, the list is created again. This should be optimized in the future to not remove and create objects that will be in the list before and after the update method. */ void ChildrenManagerImpl::Update (bool bCreateNewObjectsOnDemand) { if (maShapeTreeInfo.GetViewForwarder() == NULL) return; Rectangle aVisibleArea = maShapeTreeInfo.GetViewForwarder()->GetVisibleArea(); // 1. Create a local list of visible shapes. ChildDescriptorListType aChildList; CreateListOfVisibleShapes (aChildList); // 2. Merge the information that is already known about the visible // shapes from the current list into the new list. MergeAccessibilityInformation (aChildList); // 3. Replace the current list of visible shapes with the new one. Do // the same with the visible area. { ::osl::MutexGuard aGuard (maMutex); adjustIndexInParentOfShapes(aChildList); // Use swap to copy the contents of the new list in constant time. maVisibleChildren.swap (aChildList); // aChildList now contains all the old children, while maVisibleChildren // contains all the current children // 4. Find all shapes in the old list that are not in the current list, // send appropriate events and remove the accessible shape. // // Do this *after* we have set our new list of children, because // removing a child may cause // // ChildDescriptor::disposeAccessibleObject --> // AccessibleContextBase::CommitChange --> // AtkListener::notifyEvent -> // AtkListener::handleChildRemoved -> // AtkListener::updateChildList // AccessibleDrawDocumentView::getAccessibleChildCount -> // ChildrenManagerImpl::GetChildCount -> // maVisibleChildren.size() // // to be fired, and so the operations will take place on // the list we are trying to replace // RemoveNonVisibleChildren (maVisibleChildren, aChildList); aChildList.clear(); maVisibleArea = aVisibleArea; } // 5. If the visible area has changed then send events that signal a // change of their bounding boxes for all shapes that are members of // both the current and the new list of visible shapes. if (maVisibleArea != aVisibleArea) SendVisibleAreaEvents (maVisibleChildren); // 6. If children have to be created immediately and not on demand then // create the missing accessible objects now. if ( ! bCreateNewObjectsOnDemand) CreateAccessibilityObjects (maVisibleChildren); } void ChildrenManagerImpl::CreateListOfVisibleShapes ( ChildDescriptorListType& raDescriptorList) { ::osl::MutexGuard aGuard (maMutex); OSL_ASSERT (maShapeTreeInfo.GetViewForwarder() != NULL); Rectangle aVisibleArea = maShapeTreeInfo.GetViewForwarder()->GetVisibleArea(); // Add the visible shapes for wich the accessible objects already exist. AccessibleShapeList::iterator I,aEnd = maAccessibleShapes.end(); for (I=maAccessibleShapes.begin(); I != aEnd; ++I) { if (I->is()) { uno::Reference xComponent ( (*I)->getAccessibleContext(), uno::UNO_QUERY); if (xComponent.is()) { // The bounding box of the object already is clipped to the // visible area. The object is therefore visible if the // bounding box has non-zero extensions. awt::Rectangle aPixelBBox (xComponent->getBounds()); if ((aPixelBBox.Width > 0) && (aPixelBBox.Height > 0)) raDescriptorList.push_back (ChildDescriptor (*I)); } } } // Add the visible shapes for which only the XShapes exist. uno::Reference xShapeAccess (mxShapeList, uno::UNO_QUERY); if (xShapeAccess.is()) { sal_Int32 nShapeCount = xShapeAccess->getCount(); raDescriptorList.reserve( nShapeCount ); awt::Point aPos; awt::Size aSize; Rectangle aBoundingBox; uno::Reference xShape; for (sal_Int32 i=0; igetByIndex(i) >>= xShape; aPos = xShape->getPosition(); aSize = xShape->getSize(); aBoundingBox.nLeft = aPos.X; aBoundingBox.nTop = aPos.Y; aBoundingBox.nRight = aPos.X + aSize.Width; aBoundingBox.nBottom = aPos.Y + aSize.Height; // Insert shape if it is visible, i.e. its bounding box overlaps // the visible area. if ( aBoundingBox.IsOver (aVisibleArea) ) raDescriptorList.push_back (ChildDescriptor (xShape)); } } } void ChildrenManagerImpl::RemoveNonVisibleChildren ( const ChildDescriptorListType& rNewChildList, ChildDescriptorListType& rOldChildList) { // Iterate over list of formerly visible children and remove those that // are not visible anymore, i.e. member of the new list of visible // children. ChildDescriptorListType::iterator I, aEnd = rOldChildList.end(); for (I=rOldChildList.begin(); I != aEnd; ++I) { if (::std::find(rNewChildList.begin(), rNewChildList.end(), *I) == rNewChildList.end()) { // The child is disposed when there is a UNO shape from which // the accessible shape can be created when the shape becomes // visible again. When there is no such UNO shape then simply // reset the descriptor but keep the accessibility object. if (I->mxShape.is()) { UnregisterAsDisposeListener (I->mxShape); I->disposeAccessibleObject (mrContext); } else { AccessibleShape* pAccessibleShape = I->GetAccessibleShape(); pAccessibleShape->ResetState (AccessibleStateType::VISIBLE); I->mxAccessibleShape = NULL; } } } } void ChildrenManagerImpl::MergeAccessibilityInformation ( ChildDescriptorListType& raNewChildList) { ChildDescriptorListType::iterator aOldChildDescriptor; ChildDescriptorListType::iterator I, aEnd = raNewChildList.end(); for (I=raNewChildList.begin(); I != aEnd; ++I) { aOldChildDescriptor = ::std::find (maVisibleChildren.begin(), maVisibleChildren.end(), *I); // Copy accessible shape if that exists in the old descriptor. bool bRegistrationIsNecessary = true; if (aOldChildDescriptor != maVisibleChildren.end()) if (aOldChildDescriptor->mxAccessibleShape.is()) { I->mxAccessibleShape = aOldChildDescriptor->mxAccessibleShape; I->mbCreateEventPending = false; bRegistrationIsNecessary = false; } if (bRegistrationIsNecessary) RegisterAsDisposeListener (I->mxShape); } } void ChildrenManagerImpl::SendVisibleAreaEvents ( ChildDescriptorListType& raNewChildList) { ChildDescriptorListType::iterator I,aEnd = raNewChildList.end(); for (I=raNewChildList.begin(); I != aEnd; ++I) { // Tell shape of changed visible area. To do this, fake a // change of the view forwarder. (Actually we usually get here // as a result of a change of the view forwarder). AccessibleShape* pShape = I->GetAccessibleShape (); if (pShape != NULL) pShape->ViewForwarderChanged ( IAccessibleViewForwarderListener::VISIBLE_AREA, maShapeTreeInfo.GetViewForwarder()); } } void ChildrenManagerImpl::CreateAccessibilityObjects ( ChildDescriptorListType& raNewChildList) { ChildDescriptorListType::iterator I, aEnd = raNewChildList.end(); sal_Int32 nPos = 0; for ( I = raNewChildList.begin(); I != aEnd; ++I,++nPos) { // Create the associated accessible object when the flag says so and // it does not yet exist. if ( ! I->mxAccessibleShape.is() ) GetChild (*I,nPos); if (I->mxAccessibleShape.is() && I->mbCreateEventPending) { I->mbCreateEventPending = false; mrContext.CommitChange ( AccessibleEventId::CHILD, uno::makeAny(I->mxAccessibleShape), uno::Any()); } } } void ChildrenManagerImpl::AddShape (const Reference& rxShape) { if (rxShape.is()) { ::osl::ClearableMutexGuard aGuard (maMutex); // Test visibility of the shape. Rectangle aVisibleArea = maShapeTreeInfo.GetViewForwarder()->GetVisibleArea(); awt::Point aPos = rxShape->getPosition(); awt::Size aSize = rxShape->getSize(); Rectangle aBoundingBox ( aPos.X, aPos.Y, aPos.X + aSize.Width, aPos.Y + aSize.Height); // Add the shape only when it belongs to the list of shapes stored // in mxShapeList (which is either a page or a group shape). Reference xChild (rxShape, uno::UNO_QUERY); if (xChild.is()) { Reference xParent (xChild->getParent(), uno::UNO_QUERY); if (xParent == mxShapeList) if (aBoundingBox.IsOver (aVisibleArea)) { // Add shape to list of visible shapes. maVisibleChildren.push_back (ChildDescriptor (rxShape)); // Create accessibility object. ChildDescriptor& rDescriptor = maVisibleChildren.back(); GetChild (rDescriptor, maVisibleChildren.size()-1); // Inform listeners about new child. uno::Any aNewShape; aNewShape <<= rDescriptor.mxAccessibleShape; aGuard.clear(); mrContext.CommitChange ( AccessibleEventId::CHILD, aNewShape, uno::Any()); RegisterAsDisposeListener (rDescriptor.mxShape); } } } } void ChildrenManagerImpl::RemoveShape (const Reference& rxShape) { if (rxShape.is()) { ::osl::ClearableMutexGuard aGuard (maMutex); // Search shape in list of visible children. ChildDescriptorListType::iterator I ( ::std::find (maVisibleChildren.begin(), maVisibleChildren.end(), ChildDescriptor (rxShape))); if (I != maVisibleChildren.end()) { // Remove descriptor from that list. Reference xAccessibleShape (I->mxAccessibleShape); UnregisterAsDisposeListener (I->mxShape); // Dispose the accessible object. I->disposeAccessibleObject (mrContext); // Now we can safely remove the child descriptor and thus // invalidate the iterator. maVisibleChildren.erase (I); adjustIndexInParentOfShapes(maVisibleChildren); } } } void ChildrenManagerImpl::SetShapeList (const ::com::sun::star::uno::Reference< ::com::sun::star::drawing::XShapes>& xShapeList) { mxShapeList = xShapeList; } void ChildrenManagerImpl::AddAccessibleShape (std::auto_ptr pShape) { if (pShape.get() != NULL) maAccessibleShapes.push_back (pShape.release()); } void ChildrenManagerImpl::ClearAccessibleShapeList (void) { // Copy the list of (visible) shapes to local lists and clear the // originals. ChildDescriptorListType aLocalVisibleChildren; aLocalVisibleChildren.swap(maVisibleChildren); AccessibleShapeList aLocalAccessibleShapes; aLocalAccessibleShapes.swap(maAccessibleShapes); // Tell the listeners that all children are gone. mrContext.CommitChange ( AccessibleEventId::INVALIDATE_ALL_CHILDREN, uno::Any(), uno::Any()); // There are no accessible shapes left so the index assigned to new // accessible shapes can be reset. mnNewNameIndex = 1; // Now the objects in the local lists can be safely disposed without // having problems with callers that want to update their child lists. // Clear the list of visible accessible objects. Objects not created on // demand for XShapes are treated below. ChildDescriptorListType::iterator I,aEnd = aLocalVisibleChildren.end(); for (I=aLocalVisibleChildren.begin(); I != aEnd; ++I) if ( I->mxAccessibleShape.is() && I->mxShape.is() ) { ::comphelper::disposeComponent(I->mxAccessibleShape); I->mxAccessibleShape = NULL; } // Dispose all objects in the accessible shape list. AccessibleShapeList::iterator J,aEnd2 = aLocalAccessibleShapes.end(); for (J=aLocalAccessibleShapes.begin(); J != aEnd2; ++J) if (J->is()) { // Dispose the object. ::comphelper::disposeComponent(*J); *J = NULL; } } /** If the broadcasters change at which this object is registered then unregister at old and register at new broadcasters. */ void ChildrenManagerImpl::SetInfo (const AccessibleShapeTreeInfo& rShapeTreeInfo) { // Remember the current broadcasters and exchange the shape tree info. Reference xCurrentBroadcaster; Reference xCurrentController; Reference xCurrentSelectionSupplier; { ::osl::MutexGuard aGuard (maMutex); xCurrentBroadcaster = maShapeTreeInfo.GetModelBroadcaster(); xCurrentController = maShapeTreeInfo.GetController(); xCurrentSelectionSupplier = Reference ( xCurrentController, uno::UNO_QUERY); maShapeTreeInfo = rShapeTreeInfo; } // Move registration to new model. if (maShapeTreeInfo.GetModelBroadcaster() != xCurrentBroadcaster) { // Register at new broadcaster. if (maShapeTreeInfo.GetModelBroadcaster().is()) maShapeTreeInfo.GetModelBroadcaster()->addEventListener ( static_cast(this)); // Unregister at old broadcaster. if (xCurrentBroadcaster.is()) xCurrentBroadcaster->removeEventListener ( static_cast(this)); } // Move registration to new selection supplier. Reference xNewController(maShapeTreeInfo.GetController()); Reference xNewSelectionSupplier ( xNewController, uno::UNO_QUERY); if (xNewSelectionSupplier != xCurrentSelectionSupplier) { // Register at new broadcaster. if (xNewSelectionSupplier.is()) { xNewController->addEventListener( static_cast(this)); xNewSelectionSupplier->addSelectionChangeListener ( static_cast(this)); } // Unregister at old broadcaster. if (xCurrentSelectionSupplier.is()) { xCurrentSelectionSupplier->removeSelectionChangeListener ( static_cast(this)); xCurrentController->removeEventListener( static_cast(this)); } } } //===== lang::XEventListener ================================================ void SAL_CALL ChildrenManagerImpl::disposing (const lang::EventObject& rEventObject) throw (uno::RuntimeException) { if (rEventObject.Source == maShapeTreeInfo.GetModelBroadcaster() || rEventObject.Source == maShapeTreeInfo.GetController()) { impl_dispose(); } // Handle disposing UNO shapes. else { Reference xShape (rEventObject.Source, uno::UNO_QUERY); // Find the descriptor for the given shape. ChildDescriptorListType::iterator I ( ::std::find (maVisibleChildren.begin(), maVisibleChildren.end(), ChildDescriptor (xShape))); if (I != maVisibleChildren.end()) { // Clear the descriptor. I->disposeAccessibleObject (mrContext); I->mxShape = NULL; } } } //===== document::XEventListener ============================================ /** Listen for new and removed shapes. */ void SAL_CALL ChildrenManagerImpl::notifyEvent ( const document::EventObject& rEventObject) throw (uno::RuntimeException) { static const ::rtl::OUString sShapeInserted ( RTL_CONSTASCII_USTRINGPARAM("ShapeInserted")); static const ::rtl::OUString sShapeRemoved ( RTL_CONSTASCII_USTRINGPARAM("ShapeRemoved")); if (rEventObject.EventName.equals (sShapeInserted)) AddShape (Reference(rEventObject.Source, uno::UNO_QUERY)); else if (rEventObject.EventName.equals (sShapeRemoved)) RemoveShape (Reference(rEventObject.Source, uno::UNO_QUERY)); // else ignore unknown event. } //===== view::XSelectionChangeListener ====================================== void SAL_CALL ChildrenManagerImpl::selectionChanged (const lang::EventObject& /*rEvent*/) throw (uno::RuntimeException) { UpdateSelection (); } void ChildrenManagerImpl::impl_dispose (void) { Reference xController(maShapeTreeInfo.GetController()); // Remove from broadcasters. try { Reference xSelectionSupplier ( xController, uno::UNO_QUERY); if (xSelectionSupplier.is()) { xSelectionSupplier->removeSelectionChangeListener ( static_cast(this)); } } catch( uno::RuntimeException&) {} try { if (xController.is()) xController->removeEventListener( static_cast(this)); } catch( uno::RuntimeException&) {} maShapeTreeInfo.SetController (NULL); try { // Remove from broadcaster. if (maShapeTreeInfo.GetModelBroadcaster().is()) maShapeTreeInfo.GetModelBroadcaster()->removeEventListener ( static_cast(this)); maShapeTreeInfo.SetModelBroadcaster (NULL); } catch( uno::RuntimeException& ) {} ClearAccessibleShapeList (); SetShapeList (NULL); } void SAL_CALL ChildrenManagerImpl::disposing (void) { impl_dispose(); } // This method is experimental. Use with care. long int ChildrenManagerImpl::GetChildIndex (const ::com::sun::star::uno::Reference< ::com::sun::star::accessibility::XAccessible>& xChild) const throw (::com::sun::star::uno::RuntimeException) { ::osl::MutexGuard aGuard (maMutex); sal_Int32 nCount = maVisibleChildren.size(); for (sal_Int32 i=0; i < nCount; ++i) { // Is this equality comparison valid? if (maVisibleChildren[i].mxAccessibleShape == xChild) return i; } return -1; } //===== IAccessibleViewForwarderListener ==================================== void ChildrenManagerImpl::ViewForwarderChanged (ChangeType aChangeType, const IAccessibleViewForwarder* pViewForwarder) { if (aChangeType == IAccessibleViewForwarderListener::VISIBLE_AREA) Update (false); else { ::osl::MutexGuard aGuard (maMutex); ChildDescriptorListType::iterator I, aEnd = maVisibleChildren.end(); for (I=maVisibleChildren.begin(); I != aEnd; ++I) { AccessibleShape* pShape = I->GetAccessibleShape(); if (pShape != NULL) pShape->ViewForwarderChanged (aChangeType, pViewForwarder); } } } //===== IAccessibleParent =================================================== sal_Bool ChildrenManagerImpl::ReplaceChild ( AccessibleShape* pCurrentChild, const ::com::sun::star::uno::Reference< ::com::sun::star::drawing::XShape >& _rxShape, const long _nIndex, const AccessibleShapeTreeInfo& _rShapeTreeInfo) throw (uno::RuntimeException) { AccessibleShapeInfo aShapeInfo( _rxShape, pCurrentChild->getAccessibleParent(), this, _nIndex ); // create the new child AccessibleShape* pNewChild = ShapeTypeHandler::Instance().CreateAccessibleObject ( aShapeInfo, _rShapeTreeInfo ); Reference< XAccessible > xNewChild( pNewChild ); // keep this alive (do this before calling Init!) if ( pNewChild ) pNewChild->Init(); sal_Bool bResult = sal_False; // Iterate over the visible children. If one of them has an already // created accessible object that matches pCurrentChild then replace // it. Otherwise the child to replace is either not in the list or has // not ye been created (and is therefore not in the list, too) and a // replacement is not necessary. ChildDescriptorListType::iterator I,aEnd = maVisibleChildren.end(); for (I=maVisibleChildren.begin(); I != aEnd; ++I) { if (I->GetAccessibleShape() == pCurrentChild) { // Dispose the current child and send an event about its deletion. pCurrentChild->dispose(); mrContext.CommitChange ( AccessibleEventId::CHILD, uno::Any(), uno::makeAny (I->mxAccessibleShape)); // Replace with replacement and send an event about existance // of the new child. I->mxAccessibleShape = pNewChild; mrContext.CommitChange ( AccessibleEventId::CHILD, uno::makeAny (I->mxAccessibleShape), uno::Any()); bResult = sal_True; break; } } // When not found among the visible children we have to search the list // of accessible shapes. This is not yet implemented. return bResult; } /** Update the SELECTED and the FOCUSED state of all visible children. Maybe this should be changed to all children. Iterate over all descriptors of visible accessible shapes and look them up in the selection. If there is no valid controller then all shapes are deselected and unfocused. If the controller's frame is not active then all shapes are unfocused. */ void ChildrenManagerImpl::UpdateSelection (void) { Reference xController(maShapeTreeInfo.GetController()); Reference xSelectionSupplier ( xController, uno::UNO_QUERY); // Try to cast the selection both to a multi selection and to a single // selection. Reference xSelectedShapeAccess; Reference xSelectedShape; if (xSelectionSupplier.is()) { xSelectedShapeAccess = Reference ( xSelectionSupplier->getSelection(), uno::UNO_QUERY); xSelectedShape = Reference ( xSelectionSupplier->getSelection(), uno::UNO_QUERY); } // Remember the current and new focused shape. AccessibleShape* pCurrentlyFocusedShape = NULL; AccessibleShape* pNewFocusedShape = NULL; ChildDescriptorListType::iterator I, aEnd = maVisibleChildren.end(); for (I=maVisibleChildren.begin(); I != aEnd; ++I) { AccessibleShape* pAccessibleShape = I->GetAccessibleShape(); if (I->mxAccessibleShape.is() && I->mxShape.is() && pAccessibleShape!=NULL) { bool bShapeIsSelected = false; // Look up the shape in the (single or multi-) selection. if (xSelectedShape.is()) { if (I->mxShape == xSelectedShape) { bShapeIsSelected = true; pNewFocusedShape = pAccessibleShape; } } else if (xSelectedShapeAccess.is()) { sal_Int32 nCount=xSelectedShapeAccess->getCount(); for (sal_Int32 i=0; igetByIndex(i) == I->mxShape) { bShapeIsSelected = true; // In a multi-selection no shape has the focus. if (nCount == 1) pNewFocusedShape = pAccessibleShape; } } // Set or reset the SELECTED state. if (bShapeIsSelected) pAccessibleShape->SetState (AccessibleStateType::SELECTED); else pAccessibleShape->ResetState (AccessibleStateType::SELECTED); // Does the shape have the current selection? if (pAccessibleShape->GetState (AccessibleStateType::FOCUSED)) pCurrentlyFocusedShape = pAccessibleShape; } } // Check if the frame we are in is currently active. If not then make // sure to not send a FOCUSED state change. if (xController.is()) { Reference xFrame (xController->getFrame()); if (xFrame.is()) if ( ! xFrame->isActive()) pNewFocusedShape = NULL; } // Move focus from current to newly focused shape. if (pCurrentlyFocusedShape != pNewFocusedShape) { if (pCurrentlyFocusedShape != NULL) pCurrentlyFocusedShape->ResetState (AccessibleStateType::FOCUSED); if (pNewFocusedShape != NULL) pNewFocusedShape->SetState (AccessibleStateType::FOCUSED); } // Remember whether there is a shape that now has the focus. mpFocusedShape = pNewFocusedShape; } bool ChildrenManagerImpl::HasFocus (void) { return mpFocusedShape != NULL; } void ChildrenManagerImpl::RemoveFocus (void) { if (mpFocusedShape != NULL) { mpFocusedShape->ResetState (AccessibleStateType::FOCUSED); mpFocusedShape = NULL; } } void ChildrenManagerImpl::RegisterAsDisposeListener ( const Reference& xShape) { Reference xComponent (xShape, uno::UNO_QUERY); if (xComponent.is()) xComponent->addEventListener ( static_cast(this)); } void ChildrenManagerImpl::UnregisterAsDisposeListener ( const Reference& xShape) { Reference xComponent (xShape, uno::UNO_QUERY); if (xComponent.is()) xComponent->removeEventListener ( static_cast(this)); } //===== AccessibleChildDescriptor =========================================== ChildDescriptor::ChildDescriptor (const Reference& xShape) : mxShape (xShape), mxAccessibleShape (NULL), mbCreateEventPending (true) { // Empty. } ChildDescriptor::ChildDescriptor (const Reference& rxAccessibleShape) : mxShape (NULL), mxAccessibleShape (rxAccessibleShape), mbCreateEventPending (true) { // Make sure that the accessible object has the VISIBLE // state set. AccessibleShape* pAccessibleShape = GetAccessibleShape(); pAccessibleShape->SetState (AccessibleStateType::VISIBLE); } ChildDescriptor::~ChildDescriptor (void) { } AccessibleShape* ChildDescriptor::GetAccessibleShape (void) const { return static_cast (mxAccessibleShape.get()); } // ----------------------------------------------------------------------------- void ChildDescriptor::setIndexAtAccessibleShape(sal_Int32 _nIndex) { AccessibleShape* pShape = GetAccessibleShape(); if ( pShape ) pShape->setIndexInParent(_nIndex); } // ----------------------------------------------------------------------------- void ChildDescriptor::disposeAccessibleObject (AccessibleContextBase& rParent) { if (mxAccessibleShape.is()) { // Send event that the shape has been removed. uno::Any aOldValue; aOldValue <<= mxAccessibleShape; rParent.CommitChange ( AccessibleEventId::CHILD, uno::Any(), aOldValue); // Dispose and remove the object. Reference xComponent (mxAccessibleShape, uno::UNO_QUERY); if (xComponent.is()) xComponent->dispose (); mxAccessibleShape = NULL; } } } // end of namespace accessibility