/* * Copyright 1995-2007 Sun Microsystems, Inc. All Rights Reserved. * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. * * This code is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 only, as * published by the Free Software Foundation. Sun designates this * particular file as subject to the "Classpath" exception as provided * by Sun in the LICENSE file that accompanied this code. * * This code 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 * version 2 for more details (a copy is included in the LICENSE file that * accompanied this code). * * You should have received a copy of the GNU General Public License version * 2 along with this work; if not, write to the Free Software Foundation, * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. * * Please contact Sun Microsystems, Inc., 4150 Network Circle, Santa Clara, * CA 95054 USA or visit www.sun.com if you need additional information or * have any questions. */ package java.awt; import java.awt.dnd.DropTarget; import java.awt.event.*; import java.awt.peer.ContainerPeer; import java.awt.peer.ComponentPeer; import java.awt.peer.LightweightPeer; import java.beans.PropertyChangeListener; import java.io.IOException; import java.io.ObjectInputStream; import java.io.ObjectOutputStream; import java.io.ObjectStreamField; import java.io.PrintStream; import java.io.PrintWriter; import java.util.Arrays; import java.util.EventListener; import java.util.HashSet; import java.util.Iterator; import java.util.LinkedList; import java.util.Set; import java.util.logging.*; import javax.accessibility.*; import sun.awt.AppContext; import sun.awt.CausedFocusEvent; import sun.awt.PeerEvent; import sun.awt.SunToolkit; import sun.awt.dnd.SunDropTargetEvent; import sun.java2d.pipe.Region; /** * A generic Abstract Window Toolkit(AWT) container object is a component * that can contain other AWT components. *

* Components added to a container are tracked in a list. The order * of the list will define the components' front-to-back stacking order * within the container. If no index is specified when adding a * component to a container, it will be added to the end of the list * (and hence to the bottom of the stacking order). *

* Note: For details on the focus subsystem, see * * How to Use the Focus Subsystem, * a section in The Java Tutorial, and the * Focus Specification * for more information. * * @author Arthur van Hoff * @author Sami Shaio * @see #add(java.awt.Component, int) * @see #getComponent(int) * @see LayoutManager * @since JDK1.0 */ public class Container extends Component { private static final Logger log = Logger.getLogger("java.awt.Container"); private static final Logger eventLog = Logger.getLogger("java.awt.event.Container"); /** * The number of components in this container. * This value can be null. * @see #getComponent * @see #getComponents * @see #getComponentCount */ int ncomponents; /** * The components in this container. * @see #add * @see #getComponents */ Component component[] = new Component[0]; /** * Layout manager for this container. * @see #doLayout * @see #setLayout * @see #getLayout */ LayoutManager layoutMgr; /** * Event router for lightweight components. If this container * is native, this dispatcher takes care of forwarding and * retargeting the events to lightweight components contained * (if any). */ private LightweightDispatcher dispatcher; /** * The focus traversal policy that will manage keyboard traversal of this * Container's children, if this Container is a focus cycle root. If the * value is null, this Container inherits its policy from its focus-cycle- * root ancestor. If all such ancestors of this Container have null * policies, then the current KeyboardFocusManager's default policy is * used. If the value is non-null, this policy will be inherited by all * focus-cycle-root children that have no keyboard-traversal policy of * their own (as will, recursively, their focus-cycle-root children). *

* If this Container is not a focus cycle root, the value will be * remembered, but will not be used or inherited by this or any other * Containers until this Container is made a focus cycle root. * * @see #setFocusTraversalPolicy * @see #getFocusTraversalPolicy * @since 1.4 */ private transient FocusTraversalPolicy focusTraversalPolicy; /** * Indicates whether this Component is the root of a focus traversal cycle. * Once focus enters a traversal cycle, typically it cannot leave it via * focus traversal unless one of the up- or down-cycle keys is pressed. * Normal traversal is limited to this Container, and all of this * Container's descendants that are not descendants of inferior focus cycle * roots. * * @see #setFocusCycleRoot * @see #isFocusCycleRoot * @since 1.4 */ private boolean focusCycleRoot = false; /** * Stores the value of focusTraversalPolicyProvider property. * @since 1.5 * @see #setFocusTraversalPolicyProvider */ private boolean focusTraversalPolicyProvider; // keeps track of the threads that are printing this component private transient Set printingThreads; // True if there is at least one thread that's printing this component private transient boolean printing = false; transient ContainerListener containerListener; /* HierarchyListener and HierarchyBoundsListener support */ transient int listeningChildren; transient int listeningBoundsChildren; transient int descendantsCount; /** * JDK 1.1 serialVersionUID */ private static final long serialVersionUID = 4613797578919906343L; /** * A constant which toggles one of the controllable behaviors * of getMouseEventTarget. It is used to specify whether * the method can return the Container on which it is originally called * in case if none of its children are the current mouse event targets. * * @see #getMouseEventTarget(int, int, boolean, boolean, boolean) */ static final boolean INCLUDE_SELF = true; /** * A constant which toggles one of the controllable behaviors * of getMouseEventTarget. It is used to specify whether * the method should search only lightweight components. * * @see #getMouseEventTarget(int, int, boolean, boolean, boolean) */ static final boolean SEARCH_HEAVYWEIGHTS = true; /* * Number of HW or LW components in this container (including * all descendant containers). */ private transient int numOfHWComponents = 0; private transient int numOfLWComponents = 0; private static final Logger mixingLog = Logger.getLogger("java.awt.mixing.Container"); /** * @serialField ncomponents int * The number of components in this container. * This value can be null. * @serialField component Component[] * The components in this container. * @serialField layoutMgr LayoutManager * Layout manager for this container. * @serialField dispatcher LightweightDispatcher * Event router for lightweight components. If this container * is native, this dispatcher takes care of forwarding and * retargeting the events to lightweight components contained * (if any). * @serialField maxSize Dimension * Maximum size of this Container. * @serialField focusCycleRoot boolean * Indicates whether this Component is the root of a focus traversal cycle. * Once focus enters a traversal cycle, typically it cannot leave it via * focus traversal unless one of the up- or down-cycle keys is pressed. * Normal traversal is limited to this Container, and all of this * Container's descendants that are not descendants of inferior focus cycle * roots. * @serialField containerSerializedDataVersion int * Container Serial Data Version. * @serialField focusTraversalPolicyProvider boolean * Stores the value of focusTraversalPolicyProvider property. */ private static final ObjectStreamField[] serialPersistentFields = { new ObjectStreamField("ncomponents", Integer.TYPE), new ObjectStreamField("component", Component[].class), new ObjectStreamField("layoutMgr", LayoutManager.class), new ObjectStreamField("dispatcher", LightweightDispatcher.class), new ObjectStreamField("maxSize", Dimension.class), new ObjectStreamField("focusCycleRoot", Boolean.TYPE), new ObjectStreamField("containerSerializedDataVersion", Integer.TYPE), new ObjectStreamField("focusTraversalPolicyProvider", Boolean.TYPE), }; static { /* ensure that the necessary native libraries are loaded */ Toolkit.loadLibraries(); if (!GraphicsEnvironment.isHeadless()) { initIDs(); } } /** * Initialize JNI field and method IDs for fields that may be called from C. */ private static native void initIDs(); /** * Constructs a new Container. Containers can be extended directly, * but are lightweight in this case and must be contained by a parent * somewhere higher up in the component tree that is native. * (such as Frame for example). */ public Container() { } void initializeFocusTraversalKeys() { focusTraversalKeys = new Set[4]; } /** * Gets the number of components in this panel. * @return the number of components in this panel. * @see #getComponent * @since JDK1.1 */ public int getComponentCount() { return countComponents(); } /** * @deprecated As of JDK version 1.1, * replaced by getComponentCount(). */ @Deprecated public int countComponents() { return ncomponents; } /** * Gets the nth component in this container. * @param n the index of the component to get. * @return the nth component in this container. * @exception ArrayIndexOutOfBoundsException * if the nth value does not exist. */ public Component getComponent(int n) { synchronized (getTreeLock()) { if ((n < 0) || (n >= ncomponents)) { throw new ArrayIndexOutOfBoundsException("No such child: " + n); } return component[n]; } } /** * Gets all the components in this container. * @return an array of all the components in this container. */ public Component[] getComponents() { return getComponents_NoClientCode(); } // NOTE: This method may be called by privileged threads. // This functionality is implemented in a package-private method // to insure that it cannot be overridden by client subclasses. // DO NOT INVOKE CLIENT CODE ON THIS THREAD! final Component[] getComponents_NoClientCode() { synchronized (getTreeLock()) { return Arrays.copyOf(component, ncomponents); } } // getComponents_NoClientCode() /** * Determines the insets of this container, which indicate the size * of the container's border. *

* A Frame object, for example, has a top inset that * corresponds to the height of the frame's title bar. * @return the insets of this container. * @see Insets * @see LayoutManager * @since JDK1.1 */ public Insets getInsets() { return insets(); } /** * @deprecated As of JDK version 1.1, * replaced by getInsets(). */ @Deprecated public Insets insets() { ComponentPeer peer = this.peer; if (peer instanceof ContainerPeer) { ContainerPeer cpeer = (ContainerPeer)peer; return (Insets)cpeer.insets().clone(); } return new Insets(0, 0, 0, 0); } /** * Appends the specified component to the end of this container. * This is a convenience method for {@link #addImpl}. *

* Note: If a component has been added to a container that * has been displayed, validate must be * called on that container to display the new component. * If multiple components are being added, you can improve * efficiency by calling validate only once, * after all the components have been added. * * @param comp the component to be added * @exception NullPointerException if {@code comp} is {@code null} * @see #addImpl * @see #validate * @see javax.swing.JComponent#revalidate() * @return the component argument */ public Component add(Component comp) { addImpl(comp, null, -1); return comp; } /** * Adds the specified component to this container. * This is a convenience method for {@link #addImpl}. *

* This method is obsolete as of 1.1. Please use the * method add(Component, Object) instead. * @exception NullPointerException if {@code comp} is {@code null} * @see #add(Component, Object) */ public Component add(String name, Component comp) { addImpl(comp, name, -1); return comp; } /** * Adds the specified component to this container at the given * position. * This is a convenience method for {@link #addImpl}. *

* Note: If a component has been added to a container that * has been displayed, validate must be * called on that container to display the new component. * If multiple components are being added, you can improve * efficiency by calling validate only once, * after all the components have been added. * * @param comp the component to be added * @param index the position at which to insert the component, * or -1 to append the component to the end * @exception NullPointerException if {@code comp} is {@code null} * @exception IllegalArgumentException if {@code index} is invalid (see * {@link #addImpl} for details) * @return the component comp * @see #addImpl * @see #remove * @see #validate * @see javax.swing.JComponent#revalidate() */ public Component add(Component comp, int index) { addImpl(comp, null, index); return comp; } /** * Checks that the component comp can be added to this container * Checks : index in bounds of container's size, * comp is not one of this container's parents, * and comp is not a window. * Comp and container must be on the same GraphicsDevice. * if comp is container, all sub-components must be on * same GraphicsDevice. * * @since 1.5 */ private void checkAdding(Component comp, int index) { checkTreeLock(); GraphicsConfiguration thisGC = getGraphicsConfiguration(); if (index > ncomponents || index < 0) { throw new IllegalArgumentException("illegal component position"); } if (comp.parent == this) { if (index == ncomponents) { throw new IllegalArgumentException("illegal component position " + index + " should be less then " + ncomponents); } } if (comp instanceof Container) { for (Container cn = this; cn != null; cn=cn.parent) { if (cn == comp) { throw new IllegalArgumentException("adding container's parent to itself"); } } if (comp instanceof Window) { throw new IllegalArgumentException("adding a window to a container"); } } Window thisTopLevel = getContainingWindow(); Window compTopLevel = comp.getContainingWindow(); if (thisTopLevel != compTopLevel) { throw new IllegalArgumentException("component and container should be in the same top-level window"); } if (thisGC != null) { comp.checkGD(thisGC.getDevice().getIDstring()); } } /** * Removes component comp from this container without making unneccessary changes * and generating unneccessary events. This function intended to perform optimized * remove, for example, if newParent and current parent are the same it just changes * index without calling removeNotify. * Note: Should be called while holding treeLock * Returns whether removeNotify was invoked * @since: 1.5 */ private boolean removeDelicately(Component comp, Container newParent, int newIndex) { checkTreeLock(); int index = getComponentZOrder(comp); boolean needRemoveNotify = isRemoveNotifyNeeded(comp, this, newParent); if (needRemoveNotify) { comp.removeNotify(); } if (newParent != this) { if (layoutMgr != null) { layoutMgr.removeLayoutComponent(comp); } adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, -comp.numListening(AWTEvent.HIERARCHY_EVENT_MASK)); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, -comp.numListening(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); adjustDescendants(-(comp.countHierarchyMembers())); comp.parent = null; System.arraycopy(component, index + 1, component, index, ncomponents - index - 1); component[--ncomponents] = null; if (valid) { invalidate(); } } else { if (newIndex > index) { // 2->4: 012345 -> 013425, 2->5: 012345 -> 013452 if (newIndex-index > 0) { System.arraycopy(component, index+1, component, index, newIndex-index); } } else { // 4->2: 012345 -> 014235 if (index-newIndex > 0) { System.arraycopy(component, newIndex, component, newIndex+1, index-newIndex); } } component[newIndex] = comp; } if (comp.parent == null) { // was actually removed if (containerListener != null || (eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || Toolkit.enabledOnToolkit(AWTEvent.CONTAINER_EVENT_MASK)) { ContainerEvent e = new ContainerEvent(this, ContainerEvent.COMPONENT_REMOVED, comp); dispatchEvent(e); } comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.PARENT_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); if (peer != null && layoutMgr == null && isVisible()) { updateCursorImmediately(); } } return needRemoveNotify; } /** * Checks whether this container can contain component which is focus owner. * Verifies that container is enable and showing, and if it is focus cycle root * its FTP allows component to be focus owner * @since 1.5 */ boolean canContainFocusOwner(Component focusOwnerCandidate) { if (!(isEnabled() && isDisplayable() && isVisible() && isFocusable())) { return false; } if (isFocusCycleRoot()) { FocusTraversalPolicy policy = getFocusTraversalPolicy(); if (policy instanceof DefaultFocusTraversalPolicy) { if (!((DefaultFocusTraversalPolicy)policy).accept(focusOwnerCandidate)) { return false; } } } synchronized(getTreeLock()) { if (parent != null) { return parent.canContainFocusOwner(focusOwnerCandidate); } } return true; } /** * Checks whether or not this container has heavyweight children. * Note: Should be called while holding tree lock * @return true if there is at least one heavyweight children in a container, false otherwise * @since 1.5 */ private boolean hasHeavyweightDescendants() { checkTreeLock(); return numOfHWComponents > 0; } /** * Checks whether or not this container has lightweight children. * Note: Should be called while holding tree lock * @return true if there is at least one lightweight children in a container, false otherwise * @since 1.7 */ private boolean hasLightweightDescendants() { checkTreeLock(); return numOfLWComponents > 0; } /** * Returns closest heavyweight component to this container. If this container is heavyweight * returns this. * @since 1.5 */ Container getHeavyweightContainer() { checkTreeLock(); if (peer != null && !(peer instanceof LightweightPeer)) { return this; } else { return getNativeContainer(); } } /** * Detects whether or not remove from current parent and adding to new parent requires call of * removeNotify on the component. Since removeNotify destroys native window this might (not) * be required. For example, if new container and old containers are the same we don't need to * destroy native window. * @since: 1.5 */ private static boolean isRemoveNotifyNeeded(Component comp, Container oldContainer, Container newContainer) { if (oldContainer == null) { // Component didn't have parent - no removeNotify return false; } if (comp.peer == null) { // Component didn't have peer - no removeNotify return false; } if (newContainer.peer == null) { // Component has peer but new Container doesn't - call removeNotify return true; } // If component is lightweight non-Container or lightweight Container with all but heavyweight // children there is no need to call remove notify if (comp.isLightweight()) { boolean isContainer = comp instanceof Container; if (!isContainer || (isContainer && !((Container)comp).hasHeavyweightDescendants())) { return false; } } // If this point is reached, then the comp is either a HW or a LW container with HW descendants. // All three components have peers, check for peer change Container newNativeContainer = oldContainer.getHeavyweightContainer(); Container oldNativeContainer = newContainer.getHeavyweightContainer(); if (newNativeContainer != oldNativeContainer) { // Native containers change - check whether or not current platform supports // changing of widget hierarchy on native level without recreation. // The current implementation forbids reparenting of LW containers with HW descendants // into another native container w/o destroying the peers. Actually such an operation // is quite rare. If we ever need to save the peers, we'll have to slightly change the // addDelicately() method in order to handle such LW containers recursively, reparenting // each HW descendant independently. return !comp.peer.isReparentSupported(); } else { // if container didn't change we still might need to recreate component's window as // changes to zorder should be reflected in native window stacking order and it might // not be supported by the platform. This is important only for heavyweight child return !((ContainerPeer)(newNativeContainer.peer)).isRestackSupported(); } } /** * Moves the specified component to the specified z-order index in * the container. The z-order determines the order that components * are painted; the component with the highest z-order paints first * and the component with the lowest z-order paints last. * Where components overlap, the component with the lower * z-order paints over the component with the higher z-order. *

* If the component is a child of some other container, it is * removed from that container before being added to this container. * The important difference between this method and * java.awt.Container.add(Component, int) is that this method * doesn't call removeNotify on the component while * removing it from its previous container unless necessary and when * allowed by the underlying native windowing system. This way, if the * component has the keyboard focus, it maintains the focus when * moved to the new position. *

* This property is guaranteed to apply only to lightweight * non-Container components. *

* Note: Not all platforms support changing the z-order of * heavyweight components from one container into another without * the call to removeNotify. There is no way to detect * whether a platform supports this, so developers shouldn't make * any assumptions. * * @param comp the component to be moved * @param index the position in the container's list to * insert the component, where getComponentCount() * appends to the end * @exception NullPointerException if comp is * null * @exception IllegalArgumentException if comp is one of the * container's parents * @exception IllegalArgumentException if index is not in * the range [0, getComponentCount()] for moving * between containers, or not in the range * [0, getComponentCount()-1] for moving inside * a container * @exception IllegalArgumentException if adding a container to itself * @exception IllegalArgumentException if adding a Window * to a container * @see #getComponentZOrder(java.awt.Component) * @since 1.5 */ public void setComponentZOrder(Component comp, int index) { synchronized (getTreeLock()) { // Store parent because remove will clear it Container curParent = comp.parent; int oldZindex = getComponentZOrder(comp); if (curParent == this && index == oldZindex) { return; } checkAdding(comp, index); boolean peerRecreated = (curParent != null) ? curParent.removeDelicately(comp, this, index) : false; addDelicately(comp, curParent, index); // If the oldZindex == -1, the component gets inserted, // rather than it changes its z-order. if (!peerRecreated && oldZindex != -1) { // The new 'index' cannot be == -1. // It gets checked at the checkAdding() method. // Therefore both oldZIndex and index denote // some existing positions at this point and // this is actually a Z-order changing. comp.mixOnZOrderChanging(oldZindex, index); } } } /** * Traverses the tree of components and reparents children heavyweight component * to new heavyweight parent. * @since 1.5 */ private void reparentTraverse(ContainerPeer parentPeer, Container child) { checkTreeLock(); for (int i = 0; i < child.getComponentCount(); i++) { Component comp = child.getComponent(i); if (comp.isLightweight()) { // If components is lightweight check if it is container // If it is container it might contain heavyweight children we need to reparent if (comp instanceof Container) { reparentTraverse(parentPeer, (Container)comp); } } else { // Q: Need to update NativeInLightFixer? comp.getPeer().reparent(parentPeer); } } } /** * Reparents child component peer to this container peer. * Container must be heavyweight. * @since 1.5 */ private void reparentChild(Component comp) { checkTreeLock(); if (comp == null) { return; } if (comp.isLightweight()) { // If component is lightweight container we need to reparent all its explicit heavyweight children if (comp instanceof Container) { // Traverse component's tree till depth-first until encountering heavyweight component reparentTraverse((ContainerPeer)getPeer(), (Container)comp); } } else { comp.getPeer().reparent((ContainerPeer)getPeer()); } } /** * Adds component to this container. Tries to minimize side effects of this adding - * doesn't call remove notify if it is not required. * @since 1.5 */ private void addDelicately(Component comp, Container curParent, int index) { checkTreeLock(); // Check if moving between containers if (curParent != this) { /* Add component to list; allocate new array if necessary. */ if (ncomponents == component.length) { component = Arrays.copyOf(component, ncomponents * 2 + 1); } if (index == -1 || index == ncomponents) { component[ncomponents++] = comp; } else { System.arraycopy(component, index, component, index + 1, ncomponents - index); component[index] = comp; ncomponents++; } comp.parent = this; adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, comp.numListening(AWTEvent.HIERARCHY_EVENT_MASK)); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, comp.numListening(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); adjustDescendants(comp.countHierarchyMembers()); } else { if (index < ncomponents) { component[index] = comp; } } if (valid) { invalidate(); } if (peer != null) { if (comp.peer == null) { // Remove notify was called or it didn't have peer - create new one comp.addNotify(); // New created peer creates component on top of the stacking order Container newNativeContainer = getHeavyweightContainer(); if (((ContainerPeer)newNativeContainer.getPeer()).isRestackSupported()) { ((ContainerPeer)newNativeContainer.getPeer()).restack(); } } else { // Both container and child have peers, it means child peer should be reparented. // In both cases we need to reparent native widgets. Container newNativeContainer = getHeavyweightContainer(); Container oldNativeContainer = curParent.getHeavyweightContainer(); if (oldNativeContainer != newNativeContainer) { // Native container changed - need to reparent native widgets newNativeContainer.reparentChild(comp); } // If component still has a peer and it is either container or heavyweight // and restack is supported we have to restack native windows since order might have changed if ((!comp.isLightweight() || (comp instanceof Container)) && ((ContainerPeer)newNativeContainer.getPeer()).isRestackSupported()) { ((ContainerPeer)newNativeContainer.getPeer()).restack(); } if (!comp.isLightweight() && isLightweight()) { // If component is heavyweight and one of the containers is lightweight // the location of the component should be fixed. comp.relocateComponent(); } } } if (curParent != this) { /* Notify the layout manager of the added component. */ if (layoutMgr != null) { if (layoutMgr instanceof LayoutManager2) { ((LayoutManager2)layoutMgr).addLayoutComponent(comp, null); } else { layoutMgr.addLayoutComponent(null, comp); } } if (containerListener != null || (eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || Toolkit.enabledOnToolkit(AWTEvent.CONTAINER_EVENT_MASK)) { ContainerEvent e = new ContainerEvent(this, ContainerEvent.COMPONENT_ADDED, comp); dispatchEvent(e); } comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.PARENT_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); // If component is focus owner or parent container of focus owner check that after reparenting // focus owner moved out if new container prohibit this kind of focus owner. if (comp.isFocusOwner() && !comp.canBeFocusOwner()) { comp.transferFocus(); } else if (comp instanceof Container) { Component focusOwner = KeyboardFocusManager.getCurrentKeyboardFocusManager().getFocusOwner(); if (focusOwner != null && isParentOf(focusOwner) && !focusOwner.canBeFocusOwner()) { focusOwner.transferFocus(); } } } else { comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.HIERARCHY_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); } if (peer != null && layoutMgr == null && isVisible()) { updateCursorImmediately(); } } /** * Returns the z-order index of the component inside the container. * The higher a component is in the z-order hierarchy, the lower * its index. The component with the lowest z-order index is * painted last, above all other child components. * * @param comp the component being queried * @return the z-order index of the component; otherwise * returns -1 if the component is null * or doesn't belong to the container * @see #setComponentZOrder(java.awt.Component, int) * @since 1.5 */ public int getComponentZOrder(Component comp) { if (comp == null) { return -1; } synchronized(getTreeLock()) { // Quick check - container should be immediate parent of the component if (comp.parent != this) { return -1; } for (int i = 0; i < ncomponents; i++) { if (component[i] == comp) { return i; } } } // To please javac return -1; } /** * Adds the specified component to the end of this container. * Also notifies the layout manager to add the component to * this container's layout using the specified constraints object. * This is a convenience method for {@link #addImpl}. *

* Note: If a component has been added to a container that * has been displayed, validate must be * called on that container to display the new component. * If multiple components are being added, you can improve * efficiency by calling validate only once, * after all the components have been added. * * @param comp the component to be added * @param constraints an object expressing * layout contraints for this component * @exception NullPointerException if {@code comp} is {@code null} * @see #addImpl * @see #validate * @see javax.swing.JComponent#revalidate() * @see LayoutManager * @since JDK1.1 */ public void add(Component comp, Object constraints) { addImpl(comp, constraints, -1); } /** * Adds the specified component to this container with the specified * constraints at the specified index. Also notifies the layout * manager to add the component to the this container's layout using * the specified constraints object. * This is a convenience method for {@link #addImpl}. *

* Note: If a component has been added to a container that * has been displayed, validate must be * called on that container to display the new component. * If multiple components are being added, you can improve * efficiency by calling validate only once, * after all the components have been added. * * @param comp the component to be added * @param constraints an object expressing layout contraints for this * @param index the position in the container's list at which to insert * the component; -1 means insert at the end * component * @exception NullPointerException if {@code comp} is {@code null} * @exception IllegalArgumentException if {@code index} is invalid (see * {@link #addImpl} for details) * @see #addImpl * @see #validate * @see javax.swing.JComponent#revalidate() * @see #remove * @see LayoutManager */ public void add(Component comp, Object constraints, int index) { addImpl(comp, constraints, index); } /** * Adds the specified component to this container at the specified * index. This method also notifies the layout manager to add * the component to this container's layout using the specified * constraints object via the addLayoutComponent * method. *

* The constraints are * defined by the particular layout manager being used. For * example, the BorderLayout class defines five * constraints: BorderLayout.NORTH, * BorderLayout.SOUTH, BorderLayout.EAST, * BorderLayout.WEST, and BorderLayout.CENTER. *

* The GridBagLayout class requires a * GridBagConstraints object. Failure to pass * the correct type of constraints object results in an * IllegalArgumentException. *

* If the current layout manager implements {@code LayoutManager2}, then * {@link LayoutManager2#addLayoutComponent(Component,Object)} is invoked on * it. If the current layout manager does not implement * {@code LayoutManager2}, and constraints is a {@code String}, then * {@link LayoutManager#addLayoutComponent(String,Component)} is invoked on it. *

* If the component is not an ancestor of this container and has a non-null * parent, it is removed from its current parent before it is added to this * container. *

* This is the method to override if a program needs to track * every add request to a container as all other add methods defer * to this one. An overriding method should * usually include a call to the superclass's version of the method: *

*

* super.addImpl(comp, constraints, index) *
*

* @param comp the component to be added * @param constraints an object expressing layout constraints * for this component * @param index the position in the container's list at which to * insert the component, where -1 * means append to the end * @exception IllegalArgumentException if {@code index} is invalid; * if {@code comp} is a child of this container, the valid * range is {@code [-1, getComponentCount()-1]}; if component is * not a child of this container, the valid range is * {@code [-1, getComponentCount()]} * * @exception IllegalArgumentException if {@code comp} is an ancestor of * this container * @exception IllegalArgumentException if adding a window to a container * @exception NullPointerException if {@code comp} is {@code null} * @see #add(Component) * @see #add(Component, int) * @see #add(Component, java.lang.Object) * @see LayoutManager * @see LayoutManager2 * @since JDK1.1 */ protected void addImpl(Component comp, Object constraints, int index) { synchronized (getTreeLock()) { /* Check for correct arguments: index in bounds, * comp cannot be one of this container's parents, * and comp cannot be a window. * comp and container must be on the same GraphicsDevice. * if comp is container, all sub-components must be on * same GraphicsDevice. */ GraphicsConfiguration thisGC = this.getGraphicsConfiguration(); if (index > ncomponents || (index < 0 && index != -1)) { throw new IllegalArgumentException( "illegal component position"); } if (comp instanceof Container) { for (Container cn = this; cn != null; cn=cn.parent) { if (cn == comp) { throw new IllegalArgumentException( "adding container's parent to itself"); } } if (comp instanceof Window) { throw new IllegalArgumentException( "adding a window to a container"); } } if (thisGC != null) { comp.checkGD(thisGC.getDevice().getIDstring()); } /* Reparent the component and tidy up the tree's state. */ if (comp.parent != null) { comp.parent.remove(comp); if (index > ncomponents) { throw new IllegalArgumentException("illegal component position"); } } /* Add component to list; allocate new array if necessary. */ if (ncomponents == component.length) { component = Arrays.copyOf(component, ncomponents * 2 + 1); } if (index == -1 || index == ncomponents) { component[ncomponents++] = comp; } else { System.arraycopy(component, index, component, index + 1, ncomponents - index); component[index] = comp; ncomponents++; } comp.parent = this; adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, comp.numListening(AWTEvent.HIERARCHY_EVENT_MASK)); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, comp.numListening(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); adjustDescendants(comp.countHierarchyMembers()); if (valid) { invalidate(); } if (peer != null) { comp.addNotify(); } /* Notify the layout manager of the added component. */ if (layoutMgr != null) { if (layoutMgr instanceof LayoutManager2) { ((LayoutManager2)layoutMgr).addLayoutComponent(comp, constraints); } else if (constraints instanceof String) { layoutMgr.addLayoutComponent((String)constraints, comp); } } if (containerListener != null || (eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || Toolkit.enabledOnToolkit(AWTEvent.CONTAINER_EVENT_MASK)) { ContainerEvent e = new ContainerEvent(this, ContainerEvent.COMPONENT_ADDED, comp); dispatchEvent(e); } comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.PARENT_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); if (peer != null && layoutMgr == null && isVisible()) { updateCursorImmediately(); } } } /** * Checks that all Components that this Container contains are on * the same GraphicsDevice as this Container. If not, throws an * IllegalArgumentException. */ void checkGD(String stringID) { Component tempComp; for (int i = 0; i < component.length; i++) { tempComp= component[i]; if (tempComp != null) { tempComp.checkGD(stringID); } } } /** * Removes the component, specified by index, * from this container. * This method also notifies the layout manager to remove the * component from this container's layout via the * removeLayoutComponent method. * *

* Note: If a component has been removed from a container that * had been displayed, {@link #validate} must be * called on that container to reflect changes. * If multiple components are being removed, you can improve * efficiency by calling {@link #validate} only once, * after all the components have been removed. * * @param index the index of the component to be removed * @throws ArrayIndexOutOfBoundsException if {@code index} is not in * range {@code [0, getComponentCount()-1]} * @see #add * @see #validate * @see #getComponentCount * @since JDK1.1 */ public void remove(int index) { synchronized (getTreeLock()) { if (index < 0 || index >= ncomponents) { throw new ArrayIndexOutOfBoundsException(index); } Component comp = component[index]; if (peer != null) { comp.removeNotify(); } if (layoutMgr != null) { layoutMgr.removeLayoutComponent(comp); } adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, -comp.numListening(AWTEvent.HIERARCHY_EVENT_MASK)); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, -comp.numListening(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); adjustDescendants(-(comp.countHierarchyMembers())); comp.parent = null; System.arraycopy(component, index + 1, component, index, ncomponents - index - 1); component[--ncomponents] = null; if (valid) { invalidate(); } if (containerListener != null || (eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || Toolkit.enabledOnToolkit(AWTEvent.CONTAINER_EVENT_MASK)) { ContainerEvent e = new ContainerEvent(this, ContainerEvent.COMPONENT_REMOVED, comp); dispatchEvent(e); } comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.PARENT_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); if (peer != null && layoutMgr == null && isVisible()) { updateCursorImmediately(); } } } /** * Removes the specified component from this container. * This method also notifies the layout manager to remove the * component from this container's layout via the * removeLayoutComponent method. * *

* Note: If a component has been removed from a container that * had been displayed, {@link #validate} must be * called on that container to reflect changes. * If multiple components are being removed, you can improve * efficiency by calling {@link #validate} only once, * after all the components have been removed. * * @param comp the component to be removed * @see #add * @see #validate * @see #remove(int) */ public void remove(Component comp) { synchronized (getTreeLock()) { if (comp.parent == this) { /* Search backwards, expect that more recent additions * are more likely to be removed. */ Component component[] = this.component; for (int i = ncomponents; --i >= 0; ) { if (component[i] == comp) { remove(i); } } } } } /** * Removes all the components from this container. * This method also notifies the layout manager to remove the * components from this container's layout via the * removeLayoutComponent method. * @see #add * @see #remove */ public void removeAll() { synchronized (getTreeLock()) { adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, -listeningChildren); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, -listeningBoundsChildren); adjustDescendants(-descendantsCount); while (ncomponents > 0) { Component comp = component[--ncomponents]; component[ncomponents] = null; if (peer != null) { comp.removeNotify(); } if (layoutMgr != null) { layoutMgr.removeLayoutComponent(comp); } comp.parent = null; if (containerListener != null || (eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || Toolkit.enabledOnToolkit(AWTEvent.CONTAINER_EVENT_MASK)) { ContainerEvent e = new ContainerEvent(this, ContainerEvent.COMPONENT_REMOVED, comp); dispatchEvent(e); } comp.createHierarchyEvents(HierarchyEvent.HIERARCHY_CHANGED, comp, this, HierarchyEvent.PARENT_CHANGED, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_EVENT_MASK)); } if (peer != null && layoutMgr == null && isVisible()) { updateCursorImmediately(); } if (valid) { invalidate(); } } } // Should only be called while holding tree lock int numListening(long mask) { int superListening = super.numListening(mask); if (mask == AWTEvent.HIERARCHY_EVENT_MASK) { if (eventLog.isLoggable(Level.FINE)) { // Verify listeningChildren is correct int sum = 0; for (int i = 0; i < ncomponents; i++) { sum += component[i].numListening(mask); } if (listeningChildren != sum) { eventLog.log(Level.FINE, "Assertion (listeningChildren == sum) failed"); } } return listeningChildren + superListening; } else if (mask == AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK) { if (eventLog.isLoggable(Level.FINE)) { // Verify listeningBoundsChildren is correct int sum = 0; for (int i = 0; i < ncomponents; i++) { sum += component[i].numListening(mask); } if (listeningBoundsChildren != sum) { eventLog.log(Level.FINE, "Assertion (listeningBoundsChildren == sum) failed"); } } return listeningBoundsChildren + superListening; } else { // assert false; if (eventLog.isLoggable(Level.FINE)) { eventLog.log(Level.FINE, "This code must never be reached"); } return superListening; } } // Should only be called while holding tree lock void adjustListeningChildren(long mask, int num) { if (eventLog.isLoggable(Level.FINE)) { boolean toAssert = (mask == AWTEvent.HIERARCHY_EVENT_MASK || mask == AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK || mask == (AWTEvent.HIERARCHY_EVENT_MASK | AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); if (!toAssert) { eventLog.log(Level.FINE, "Assertion failed"); } } if (num == 0) return; if ((mask & AWTEvent.HIERARCHY_EVENT_MASK) != 0) { listeningChildren += num; } if ((mask & AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK) != 0) { listeningBoundsChildren += num; } adjustListeningChildrenOnParent(mask, num); } // Should only be called while holding tree lock void adjustDescendants(int num) { if (num == 0) return; descendantsCount += num; adjustDecendantsOnParent(num); } // Should only be called while holding tree lock void adjustDecendantsOnParent(int num) { if (parent != null) { parent.adjustDescendants(num); } } // Should only be called while holding tree lock int countHierarchyMembers() { if (log.isLoggable(Level.FINE)) { // Verify descendantsCount is correct int sum = 0; for (int i = 0; i < ncomponents; i++) { sum += component[i].countHierarchyMembers(); } if (descendantsCount != sum) { log.log(Level.FINE, "Assertion (descendantsCount == sum) failed"); } } return descendantsCount + 1; } private int getListenersCount(int id, boolean enabledOnToolkit) { assert Thread.holdsLock(getTreeLock()); if (enabledOnToolkit) { return descendantsCount; } switch (id) { case HierarchyEvent.HIERARCHY_CHANGED: return listeningChildren; case HierarchyEvent.ANCESTOR_MOVED: case HierarchyEvent.ANCESTOR_RESIZED: return listeningBoundsChildren; default: return 0; } } final int createHierarchyEvents(int id, Component changed, Container changedParent, long changeFlags, boolean enabledOnToolkit) { assert Thread.holdsLock(getTreeLock()); int listeners = getListenersCount(id, enabledOnToolkit); for (int count = listeners, i = 0; count > 0; i++) { count -= component[i].createHierarchyEvents(id, changed, changedParent, changeFlags, enabledOnToolkit); } return listeners + super.createHierarchyEvents(id, changed, changedParent, changeFlags, enabledOnToolkit); } final void createChildHierarchyEvents(int id, long changeFlags, boolean enabledOnToolkit) { assert Thread.holdsLock(getTreeLock()); if (ncomponents == 0) { return; } int listeners = getListenersCount(id, enabledOnToolkit); for (int count = listeners, i = 0; count > 0; i++) { count -= component[i].createHierarchyEvents(id, this, parent, changeFlags, enabledOnToolkit); } } /** * Gets the layout manager for this container. * @see #doLayout * @see #setLayout */ public LayoutManager getLayout() { return layoutMgr; } /** * Sets the layout manager for this container. * @param mgr the specified layout manager * @see #doLayout * @see #getLayout */ public void setLayout(LayoutManager mgr) { layoutMgr = mgr; if (valid) { invalidate(); } } /** * Causes this container to lay out its components. Most programs * should not call this method directly, but should invoke * the validate method instead. * @see LayoutManager#layoutContainer * @see #setLayout * @see #validate * @since JDK1.1 */ public void doLayout() { layout(); } /** * @deprecated As of JDK version 1.1, * replaced by doLayout(). */ @Deprecated public void layout() { LayoutManager layoutMgr = this.layoutMgr; if (layoutMgr != null) { layoutMgr.layoutContainer(this); } } /** * Invalidates the container. The container and all parents * above it are marked as needing to be laid out. This method can * be called often, so it needs to execute quickly. * *

If the {@code LayoutManager} installed on this container is * an instance of {@code LayoutManager2}, then * {@link LayoutManager2#invalidateLayout(Container)} is invoked on * it supplying this {@code Container} as the argument. * * @see #validate * @see #layout * @see LayoutManager * @see LayoutManager2#invalidateLayout(Container) */ public void invalidate() { LayoutManager layoutMgr = this.layoutMgr; if (layoutMgr instanceof LayoutManager2) { LayoutManager2 lm = (LayoutManager2) layoutMgr; lm.invalidateLayout(this); } super.invalidate(); } /** * Validates this container and all of its subcomponents. *

* The validate method is used to cause a container * to lay out its subcomponents again. It should be invoked when * this container's subcomponents are modified (added to or * removed from the container, or layout-related information * changed) after the container has been displayed. * *

If this {@code Container} is not valid, this method invokes * the {@code validateTree} method and marks this {@code Container} * as valid. Otherwise, no action is performed. * * @see #add(java.awt.Component) * @see Component#invalidate * @see javax.swing.JComponent#revalidate() * @see #validateTree */ public void validate() { /* Avoid grabbing lock unless really necessary. */ if (!valid) { boolean updateCur = false; synchronized (getTreeLock()) { if (!valid && peer != null) { ContainerPeer p = null; if (peer instanceof ContainerPeer) { p = (ContainerPeer) peer; } if (p != null) { p.beginValidate(); } validateTree(); valid = true; if (p != null) { p.endValidate(); updateCur = isVisible(); } } } if (updateCur) { updateCursorImmediately(); } } } /** * Recursively descends the container tree and recomputes the * layout for any subtrees marked as needing it (those marked as * invalid). Synchronization should be provided by the method * that calls this one: validate. * * @see #doLayout * @see #validate */ protected void validateTree() { if (!valid) { if (peer instanceof ContainerPeer) { ((ContainerPeer)peer).beginLayout(); } doLayout(); Component component[] = this.component; for (int i = 0 ; i < ncomponents ; ++i) { Component comp = component[i]; if ( (comp instanceof Container) && !(comp instanceof Window) && !comp.valid) { ((Container)comp).validateTree(); } else { comp.validate(); } } if (peer instanceof ContainerPeer) { ((ContainerPeer)peer).endLayout(); } } valid = true; } /** * Recursively descends the container tree and invalidates all * contained components. */ void invalidateTree() { synchronized (getTreeLock()) { for (int i = 0; i < ncomponents; ++i) { Component comp = component[i]; if (comp instanceof Container) { ((Container)comp).invalidateTree(); } else { if (comp.valid) { comp.invalidate(); } } } if (valid) { invalidate(); } } } /** * Sets the font of this container. * @param f The font to become this container's font. * @see Component#getFont * @since JDK1.0 */ public void setFont(Font f) { boolean shouldinvalidate = false; Font oldfont = getFont(); super.setFont(f); Font newfont = getFont(); if (newfont != oldfont && (oldfont == null || !oldfont.equals(newfont))) { invalidateTree(); } } /** * Returns the preferred size of this container. If the preferred size has * not been set explicitly by {@link Component#setPreferredSize(Dimension)} * and this {@code Container} has a {@code non-null} {@link LayoutManager}, * then {@link LayoutManager#preferredLayoutSize(Container)} * is used to calculate the preferred size. * *

Note: some implementations may cache the value returned from the * {@code LayoutManager}. Implementations that cache need not invoke * {@code preferredLayoutSize} on the {@code LayoutManager} every time * this method is invoked, rather the {@code LayoutManager} will only * be queried after the {@code Container} becomes invalid. * * @return an instance of Dimension that represents * the preferred size of this container. * @see #getMinimumSize * @see #getMaximumSize * @see #getLayout * @see LayoutManager#preferredLayoutSize(Container) * @see Component#getPreferredSize */ public Dimension getPreferredSize() { return preferredSize(); } /** * @deprecated As of JDK version 1.1, * replaced by getPreferredSize(). */ @Deprecated public Dimension preferredSize() { /* Avoid grabbing the lock if a reasonable cached size value * is available. */ Dimension dim = prefSize; if (dim == null || !(isPreferredSizeSet() || isValid())) { synchronized (getTreeLock()) { prefSize = (layoutMgr != null) ? layoutMgr.preferredLayoutSize(this) : super.preferredSize(); dim = prefSize; } } if (dim != null){ return new Dimension(dim); } else{ return dim; } } /** * Returns the minimum size of this container. If the minimum size has * not been set explicitly by {@link Component#setMinimumSize(Dimension)} * and this {@code Container} has a {@code non-null} {@link LayoutManager}, * then {@link LayoutManager#minimumLayoutSize(Container)} * is used to calculate the minimum size. * *

Note: some implementations may cache the value returned from the * {@code LayoutManager}. Implementations that cache need not invoke * {@code minimumLayoutSize} on the {@code LayoutManager} every time * this method is invoked, rather the {@code LayoutManager} will only * be queried after the {@code Container} becomes invalid. * * @return an instance of Dimension that represents * the minimum size of this container. * @see #getPreferredSize * @see #getMaximumSize * @see #getLayout * @see LayoutManager#minimumLayoutSize(Container) * @see Component#getMinimumSize * @since JDK1.1 */ public Dimension getMinimumSize() { return minimumSize(); } /** * @deprecated As of JDK version 1.1, * replaced by getMinimumSize(). */ @Deprecated public Dimension minimumSize() { /* Avoid grabbing the lock if a reasonable cached size value * is available. */ Dimension dim = minSize; if (dim == null || !(isMinimumSizeSet() || isValid())) { synchronized (getTreeLock()) { minSize = (layoutMgr != null) ? layoutMgr.minimumLayoutSize(this) : super.minimumSize(); dim = minSize; } } if (dim != null){ return new Dimension(dim); } else{ return dim; } } /** * Returns the maximum size of this container. If the maximum size has * not been set explicitly by {@link Component#setMaximumSize(Dimension)} * and the {@link LayoutManager} installed on this {@code Container} * is an instance of {@link LayoutManager2}, then * {@link LayoutManager2#maximumLayoutSize(Container)} * is used to calculate the maximum size. * *

Note: some implementations may cache the value returned from the * {@code LayoutManager2}. Implementations that cache need not invoke * {@code maximumLayoutSize} on the {@code LayoutManager2} every time * this method is invoked, rather the {@code LayoutManager2} will only * be queried after the {@code Container} becomes invalid. * * @return an instance of Dimension that represents * the maximum size of this container. * @see #getPreferredSize * @see #getMinimumSize * @see #getLayout * @see LayoutManager2#maximumLayoutSize(Container) * @see Component#getMaximumSize */ public Dimension getMaximumSize() { /* Avoid grabbing the lock if a reasonable cached size value * is available. */ Dimension dim = maxSize; if (dim == null || !(isMaximumSizeSet() || isValid())) { synchronized (getTreeLock()) { if (layoutMgr instanceof LayoutManager2) { LayoutManager2 lm = (LayoutManager2) layoutMgr; maxSize = lm.maximumLayoutSize(this); } else { maxSize = super.getMaximumSize(); } dim = maxSize; } } if (dim != null){ return new Dimension(dim); } else{ return dim; } } /** * Returns the alignment along the x axis. This specifies how * the component would like to be aligned relative to other * components. The value should be a number between 0 and 1 * where 0 represents alignment along the origin, 1 is aligned * the furthest away from the origin, 0.5 is centered, etc. */ public float getAlignmentX() { float xAlign; if (layoutMgr instanceof LayoutManager2) { synchronized (getTreeLock()) { LayoutManager2 lm = (LayoutManager2) layoutMgr; xAlign = lm.getLayoutAlignmentX(this); } } else { xAlign = super.getAlignmentX(); } return xAlign; } /** * Returns the alignment along the y axis. This specifies how * the component would like to be aligned relative to other * components. The value should be a number between 0 and 1 * where 0 represents alignment along the origin, 1 is aligned * the furthest away from the origin, 0.5 is centered, etc. */ public float getAlignmentY() { float yAlign; if (layoutMgr instanceof LayoutManager2) { synchronized (getTreeLock()) { LayoutManager2 lm = (LayoutManager2) layoutMgr; yAlign = lm.getLayoutAlignmentY(this); } } else { yAlign = super.getAlignmentY(); } return yAlign; } /** * Paints the container. This forwards the paint to any lightweight * components that are children of this container. If this method is * reimplemented, super.paint(g) should be called so that lightweight * components are properly rendered. If a child component is entirely * clipped by the current clipping setting in g, paint() will not be * forwarded to that child. * * @param g the specified Graphics window * @see Component#update(Graphics) */ public void paint(Graphics g) { if (isShowing()) { synchronized (this) { if (printing) { if (printingThreads.contains(Thread.currentThread())) { return; } } } // The container is showing on screen and // this paint() is not called from print(). // Paint self and forward the paint to lightweight subcomponents. // super.paint(); -- Don't bother, since it's a NOP. GraphicsCallback.PaintCallback.getInstance(). runComponents(component, g, GraphicsCallback.LIGHTWEIGHTS); } } /** * Updates the container. This forwards the update to any lightweight * components that are children of this container. If this method is * reimplemented, super.update(g) should be called so that lightweight * components are properly rendered. If a child component is entirely * clipped by the current clipping setting in g, update() will not be * forwarded to that child. * * @param g the specified Graphics window * @see Component#update(Graphics) */ public void update(Graphics g) { if (isShowing()) { if (! (peer instanceof LightweightPeer)) { g.clearRect(0, 0, width, height); } paint(g); } } /** * Prints the container. This forwards the print to any lightweight * components that are children of this container. If this method is * reimplemented, super.print(g) should be called so that lightweight * components are properly rendered. If a child component is entirely * clipped by the current clipping setting in g, print() will not be * forwarded to that child. * * @param g the specified Graphics window * @see Component#update(Graphics) */ public void print(Graphics g) { if (isShowing()) { Thread t = Thread.currentThread(); try { synchronized (this) { if (printingThreads == null) { printingThreads = new HashSet(); } printingThreads.add(t); printing = true; } super.print(g); // By default, Component.print() calls paint() } finally { synchronized (this) { printingThreads.remove(t); printing = !printingThreads.isEmpty(); } } GraphicsCallback.PrintCallback.getInstance(). runComponents(component, g, GraphicsCallback.LIGHTWEIGHTS); } } /** * Paints each of the components in this container. * @param g the graphics context. * @see Component#paint * @see Component#paintAll */ public void paintComponents(Graphics g) { if (isShowing()) { GraphicsCallback.PaintAllCallback.getInstance(). runComponents(component, g, GraphicsCallback.TWO_PASSES); } } /** * Simulates the peer callbacks into java.awt for printing of * lightweight Containers. * @param g the graphics context to use for printing. * @see Component#printAll * @see #printComponents */ void lightweightPaint(Graphics g) { super.lightweightPaint(g); paintHeavyweightComponents(g); } /** * Prints all the heavyweight subcomponents. */ void paintHeavyweightComponents(Graphics g) { if (isShowing()) { GraphicsCallback.PaintHeavyweightComponentsCallback.getInstance(). runComponents(component, g, GraphicsCallback.LIGHTWEIGHTS | GraphicsCallback.HEAVYWEIGHTS); } } /** * Prints each of the components in this container. * @param g the graphics context. * @see Component#print * @see Component#printAll */ public void printComponents(Graphics g) { if (isShowing()) { GraphicsCallback.PrintAllCallback.getInstance(). runComponents(component, g, GraphicsCallback.TWO_PASSES); } } /** * Simulates the peer callbacks into java.awt for printing of * lightweight Containers. * @param g the graphics context to use for printing. * @see Component#printAll * @see #printComponents */ void lightweightPrint(Graphics g) { super.lightweightPrint(g); printHeavyweightComponents(g); } /** * Prints all the heavyweight subcomponents. */ void printHeavyweightComponents(Graphics g) { if (isShowing()) { GraphicsCallback.PrintHeavyweightComponentsCallback.getInstance(). runComponents(component, g, GraphicsCallback.LIGHTWEIGHTS | GraphicsCallback.HEAVYWEIGHTS); } } /** * Adds the specified container listener to receive container events * from this container. * If l is null, no exception is thrown and no action is performed. *

Refer to AWT Threading Issues for details on AWT's threading model. * * @param l the container listener * * @see #removeContainerListener * @see #getContainerListeners */ public synchronized void addContainerListener(ContainerListener l) { if (l == null) { return; } containerListener = AWTEventMulticaster.add(containerListener, l); newEventsOnly = true; } /** * Removes the specified container listener so it no longer receives * container events from this container. * If l is null, no exception is thrown and no action is performed. *

Refer to AWT Threading Issues for details on AWT's threading model. * * @param l the container listener * * @see #addContainerListener * @see #getContainerListeners */ public synchronized void removeContainerListener(ContainerListener l) { if (l == null) { return; } containerListener = AWTEventMulticaster.remove(containerListener, l); } /** * Returns an array of all the container listeners * registered on this container. * * @return all of this container's ContainerListeners * or an empty array if no container * listeners are currently registered * * @see #addContainerListener * @see #removeContainerListener * @since 1.4 */ public synchronized ContainerListener[] getContainerListeners() { return (ContainerListener[]) (getListeners(ContainerListener.class)); } /** * Returns an array of all the objects currently registered * as FooListeners * upon this Container. * FooListeners are registered using the * addFooListener method. * *

* You can specify the listenerType argument * with a class literal, such as * FooListener.class. * For example, you can query a * Container c * for its container listeners with the following code: * *

ContainerListener[] cls = (ContainerListener[])(c.getListeners(ContainerListener.class));
* * If no such listeners exist, this method returns an empty array. * * @param listenerType the type of listeners requested; this parameter * should specify an interface that descends from * java.util.EventListener * @return an array of all objects registered as * FooListeners on this container, * or an empty array if no such listeners have been added * @exception ClassCastException if listenerType * doesn't specify a class or interface that implements * java.util.EventListener * * @see #getContainerListeners * * @since 1.3 */ public T[] getListeners(Class listenerType) { EventListener l = null; if (listenerType == ContainerListener.class) { l = containerListener; } else { return super.getListeners(listenerType); } return AWTEventMulticaster.getListeners(l, listenerType); } // REMIND: remove when filtering is done at lower level boolean eventEnabled(AWTEvent e) { int id = e.getID(); if (id == ContainerEvent.COMPONENT_ADDED || id == ContainerEvent.COMPONENT_REMOVED) { if ((eventMask & AWTEvent.CONTAINER_EVENT_MASK) != 0 || containerListener != null) { return true; } return false; } return super.eventEnabled(e); } /** * Processes events on this container. If the event is a * ContainerEvent, it invokes the * processContainerEvent method, else it invokes * its superclass's processEvent. *

Note that if the event parameter is null * the behavior is unspecified and may result in an * exception. * * @param e the event */ protected void processEvent(AWTEvent e) { if (e instanceof ContainerEvent) { processContainerEvent((ContainerEvent)e); return; } super.processEvent(e); } /** * Processes container events occurring on this container by * dispatching them to any registered ContainerListener objects. * NOTE: This method will not be called unless container events * are enabled for this component; this happens when one of the * following occurs: *

*

Note that if the event parameter is null * the behavior is unspecified and may result in an * exception. * * @param e the container event * @see Component#enableEvents */ protected void processContainerEvent(ContainerEvent e) { ContainerListener listener = containerListener; if (listener != null) { switch(e.getID()) { case ContainerEvent.COMPONENT_ADDED: listener.componentAdded(e); break; case ContainerEvent.COMPONENT_REMOVED: listener.componentRemoved(e); break; } } } /* * Dispatches an event to this component or one of its sub components. * Create ANCESTOR_RESIZED and ANCESTOR_MOVED events in response to * COMPONENT_RESIZED and COMPONENT_MOVED events. We have to do this * here instead of in processComponentEvent because ComponentEvents * may not be enabled for this Container. * @param e the event */ void dispatchEventImpl(AWTEvent e) { if ((dispatcher != null) && dispatcher.dispatchEvent(e)) { // event was sent to a lightweight component. The // native-produced event sent to the native container // must be properly disposed of by the peer, so it // gets forwarded. If the native host has been removed // as a result of the sending the lightweight event, // the peer reference will be null. e.consume(); if (peer != null) { peer.handleEvent(e); } return; } super.dispatchEventImpl(e); synchronized (getTreeLock()) { switch (e.getID()) { case ComponentEvent.COMPONENT_RESIZED: createChildHierarchyEvents(HierarchyEvent.ANCESTOR_RESIZED, 0, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); break; case ComponentEvent.COMPONENT_MOVED: createChildHierarchyEvents(HierarchyEvent.ANCESTOR_MOVED, 0, Toolkit.enabledOnToolkit(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); break; default: break; } } } /* * Dispatches an event to this component, without trying to forward * it to any subcomponents * @param e the event */ void dispatchEventToSelf(AWTEvent e) { super.dispatchEventImpl(e); } /** * Fetchs the top-most (deepest) lightweight component that is interested * in receiving mouse events. */ Component getMouseEventTarget(int x, int y, boolean includeSelf) { return getMouseEventTarget(x, y, includeSelf, MouseEventTargetFilter.FILTER, !SEARCH_HEAVYWEIGHTS); } /** * Fetches the top-most (deepest) component to receive SunDropTargetEvents. */ Component getDropTargetEventTarget(int x, int y, boolean includeSelf) { return getMouseEventTarget(x, y, includeSelf, DropTargetEventTargetFilter.FILTER, SEARCH_HEAVYWEIGHTS); } /** * A private version of getMouseEventTarget which has two additional * controllable behaviors. This method searches for the top-most * descendant of this container that contains the given coordinates * and is accepted by the given filter. The search will be constrained to * lightweight descendants if the last argument is false. * * @param filter EventTargetFilter instance to determine whether the * given component is a valid target for this event. * @param searchHeavyweights if false, the method * will bypass heavyweight components during the search. */ private Component getMouseEventTarget(int x, int y, boolean includeSelf, EventTargetFilter filter, boolean searchHeavyweights) { Component comp = null; if (searchHeavyweights) { comp = getMouseEventTargetImpl(x, y, includeSelf, filter, SEARCH_HEAVYWEIGHTS, searchHeavyweights); } if (comp == null || comp == this) { comp = getMouseEventTargetImpl(x, y, includeSelf, filter, !SEARCH_HEAVYWEIGHTS, searchHeavyweights); } return comp; } /** * A private version of getMouseEventTarget which has three additional * controllable behaviors. This method searches for the top-most * descendant of this container that contains the given coordinates * and is accepted by the given filter. The search will be constrained to * descendants of only lightweight children or only heavyweight children * of this container depending on searchHeavyweightChildren. The search will * be constrained to only lightweight descendants of the searched children * of this container if searchHeavyweightDescendants is false. * * @param filter EventTargetFilter instance to determine whether the * selected component is a valid target for this event. * @param searchHeavyweightChildren if true, the method * will bypass immediate lightweight children during the search. * If false, the methods will bypass immediate * heavyweight children during the search. * @param searchHeavyweightDescendants if false, the method * will bypass heavyweight descendants which are not immediate * children during the search. If true, the method * will traverse both lightweight and heavyweight descendants during * the search. */ private Component getMouseEventTargetImpl(int x, int y, boolean includeSelf, EventTargetFilter filter, boolean searchHeavyweightChildren, boolean searchHeavyweightDescendants) { synchronized (getTreeLock()) { int ncomponents = this.ncomponents; Component component[] = this.component; for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null && comp.visible && ((!searchHeavyweightChildren && comp.peer instanceof LightweightPeer) || (searchHeavyweightChildren && !(comp.peer instanceof LightweightPeer))) && comp.contains(x - comp.x, y - comp.y)) { // found a component that intersects the point, see if there // is a deeper possibility. if (comp instanceof Container) { Container child = (Container) comp; Component deeper = child.getMouseEventTarget( x - child.x, y - child.y, includeSelf, filter, searchHeavyweightDescendants); if (deeper != null) { return deeper; } } else { if (filter.accept(comp)) { // there isn't a deeper target, but this component // is a target return comp; } } } } boolean isPeerOK; boolean isMouseOverMe; isPeerOK = (peer instanceof LightweightPeer) || includeSelf; isMouseOverMe = contains(x,y); // didn't find a child target, return this component if it's // a possible target if (isMouseOverMe && isPeerOK && filter.accept(this)) { return this; } // no possible target return null; } } static interface EventTargetFilter { boolean accept(final Component comp); } static class MouseEventTargetFilter implements EventTargetFilter { static final EventTargetFilter FILTER = new MouseEventTargetFilter(); private MouseEventTargetFilter() {} public boolean accept(final Component comp) { return (comp.eventMask & AWTEvent.MOUSE_MOTION_EVENT_MASK) != 0 || (comp.eventMask & AWTEvent.MOUSE_EVENT_MASK) != 0 || (comp.eventMask & AWTEvent.MOUSE_WHEEL_EVENT_MASK) != 0 || comp.mouseListener != null || comp.mouseMotionListener != null || comp.mouseWheelListener != null; } } static class DropTargetEventTargetFilter implements EventTargetFilter { static final EventTargetFilter FILTER = new DropTargetEventTargetFilter(); private DropTargetEventTargetFilter() {} public boolean accept(final Component comp) { DropTarget dt = comp.getDropTarget(); return dt != null && dt.isActive(); } } /** * This is called by lightweight components that want the containing * windowed parent to enable some kind of events on their behalf. * This is needed for events that are normally only dispatched to * windows to be accepted so that they can be forwarded downward to * the lightweight component that has enabled them. */ void proxyEnableEvents(long events) { if (peer instanceof LightweightPeer) { // this container is lightweight.... continue sending it // upward. if (parent != null) { parent.proxyEnableEvents(events); } } else { // This is a native container, so it needs to host // one of it's children. If this function is called before // a peer has been created we don't yet have a dispatcher // because it has not yet been determined if this instance // is lightweight. if (dispatcher != null) { dispatcher.enableEvents(events); } } } /** * @deprecated As of JDK version 1.1, * replaced by dispatchEvent(AWTEvent e) */ @Deprecated public void deliverEvent(Event e) { Component comp = getComponentAt(e.x, e.y); if ((comp != null) && (comp != this)) { e.translate(-comp.x, -comp.y); comp.deliverEvent(e); } else { postEvent(e); } } /** * Locates the component that contains the x,y position. The * top-most child component is returned in the case where there * is overlap in the components. This is determined by finding * the component closest to the index 0 that claims to contain * the given point via Component.contains(), except that Components * which have native peers take precedence over those which do not * (i.e., lightweight Components). * * @param x the x coordinate * @param y the y coordinate * @return null if the component does not contain the position. * If there is no child component at the requested point and the * point is within the bounds of the container the container itself * is returned; otherwise the top-most child is returned. * @see Component#contains * @since JDK1.1 */ public Component getComponentAt(int x, int y) { return locate(x, y); } /** * @deprecated As of JDK version 1.1, * replaced by getComponentAt(int, int). */ @Deprecated public Component locate(int x, int y) { if (!contains(x, y)) { return null; } synchronized (getTreeLock()) { // Two passes: see comment in sun.awt.SunGraphicsCallback for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null && !(comp.peer instanceof LightweightPeer)) { if (comp.contains(x - comp.x, y - comp.y)) { return comp; } } } for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null && comp.peer instanceof LightweightPeer) { if (comp.contains(x - comp.x, y - comp.y)) { return comp; } } } } return this; } /** * Gets the component that contains the specified point. * @param p the point. * @return returns the component that contains the point, * or null if the component does * not contain the point. * @see Component#contains * @since JDK1.1 */ public Component getComponentAt(Point p) { return getComponentAt(p.x, p.y); } /** * Returns the position of the mouse pointer in this Container's * coordinate space if the Container is under the mouse pointer, * otherwise returns null. * This method is similar to {@link Component#getMousePosition()} with the exception * that it can take the Container's children into account. * If allowChildren is false, this method will return * a non-null value only if the mouse pointer is above the Container * directly, not above the part obscured by children. * If allowChildren is true, this method returns * a non-null value if the mouse pointer is above Container or any * of its descendants. * * @exception HeadlessException if GraphicsEnvironment.isHeadless() returns true * @param allowChildren true if children should be taken into account * @see Component#getMousePosition * @return mouse coordinates relative to this Component, or null * @since 1.5 */ public Point getMousePosition(boolean allowChildren) throws HeadlessException { if (GraphicsEnvironment.isHeadless()) { throw new HeadlessException(); } PointerInfo pi = (PointerInfo)java.security.AccessController.doPrivileged( new java.security.PrivilegedAction() { public Object run() { return MouseInfo.getPointerInfo(); } } ); synchronized (getTreeLock()) { Component inTheSameWindow = findUnderMouseInWindow(pi); if (isSameOrAncestorOf(inTheSameWindow, allowChildren)) { return pointRelativeToComponent(pi.getLocation()); } return null; } } boolean isSameOrAncestorOf(Component comp, boolean allowChildren) { return this == comp || (allowChildren && isParentOf(comp)); } /** * Locates the visible child component that contains the specified * position. The top-most child component is returned in the case * where there is overlap in the components. If the containing child * component is a Container, this method will continue searching for * the deepest nested child component. Components which are not * visible are ignored during the search.

* * The findComponentAt method is different from getComponentAt in * that getComponentAt only searches the Container's immediate * children; if the containing component is a Container, * findComponentAt will search that child to find a nested component. * * @param x the x coordinate * @param y the y coordinate * @return null if the component does not contain the position. * If there is no child component at the requested point and the * point is within the bounds of the container the container itself * is returned. * @see Component#contains * @see #getComponentAt * @since 1.2 */ public Component findComponentAt(int x, int y) { synchronized (getTreeLock()) { return findComponentAt(x, y, true); } } /** * Private version of findComponentAt which has a controllable * behavior. Setting 'ignoreEnabled' to 'false' bypasses disabled * Components during the search. This behavior is used by the * lightweight cursor support in sun.awt.GlobalCursorManager. * The cursor code calls this function directly via native code. * * The addition of this feature is temporary, pending the * adoption of new, public API which exports this feature. */ final Component findComponentAt(int x, int y, boolean ignoreEnabled) { if (isRecursivelyVisible()){ return findComponentAtImpl(x, y, ignoreEnabled); } return null; } final Component findComponentAtImpl(int x, int y, boolean ignoreEnabled){ if (!(contains(x, y) && visible && (ignoreEnabled || enabled))) { return null; } int ncomponents = this.ncomponents; Component component[] = this.component; // Two passes: see comment in sun.awt.SunGraphicsCallback for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null && !(comp.peer instanceof LightweightPeer)) { if (comp instanceof Container) { comp = ((Container)comp).findComponentAtImpl(x - comp.x, y - comp.y, ignoreEnabled); } else { comp = comp.locate(x - comp.x, y - comp.y); } if (comp != null && comp.visible && (ignoreEnabled || comp.enabled)) { return comp; } } } for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null && comp.peer instanceof LightweightPeer) { if (comp instanceof Container) { comp = ((Container)comp).findComponentAtImpl(x - comp.x, y - comp.y, ignoreEnabled); } else { comp = comp.locate(x - comp.x, y - comp.y); } if (comp != null && comp.visible && (ignoreEnabled || comp.enabled)) { return comp; } } } return this; } /** * Locates the visible child component that contains the specified * point. The top-most child component is returned in the case * where there is overlap in the components. If the containing child * component is a Container, this method will continue searching for * the deepest nested child component. Components which are not * visible are ignored during the search.

* * The findComponentAt method is different from getComponentAt in * that getComponentAt only searches the Container's immediate * children; if the containing component is a Container, * findComponentAt will search that child to find a nested component. * * @param p the point. * @return null if the component does not contain the position. * If there is no child component at the requested point and the * point is within the bounds of the container the container itself * is returned. * @see Component#contains * @see #getComponentAt * @since 1.2 */ public Component findComponentAt(Point p) { return findComponentAt(p.x, p.y); } /** * Makes this Container displayable by connecting it to * a native screen resource. Making a container displayable will * cause all of its children to be made displayable. * This method is called internally by the toolkit and should * not be called directly by programs. * @see Component#isDisplayable * @see #removeNotify */ public void addNotify() { synchronized (getTreeLock()) { // addNotify() on the children may cause proxy event enabling // on this instance, so we first call super.addNotify() and // possibly create an lightweight event dispatcher before calling // addNotify() on the children which may be lightweight. super.addNotify(); if (! (peer instanceof LightweightPeer)) { dispatcher = new LightweightDispatcher(this); } int ncomponents = this.ncomponents; Component component[] = this.component; for (int i = 0 ; i < ncomponents ; i++) { component[i].addNotify(); } // Update stacking order if native platform allows ContainerPeer cpeer = (ContainerPeer)peer; if (cpeer.isRestackSupported()) { cpeer.restack(); } } } /** * Makes this Container undisplayable by removing its connection * to its native screen resource. Making a container undisplayable * will cause all of its children to be made undisplayable. * This method is called by the toolkit internally and should * not be called directly by programs. * @see Component#isDisplayable * @see #addNotify */ public void removeNotify() { synchronized (getTreeLock()) { int ncomponents = this.ncomponents; Component component[] = this.component; for (int i = ncomponents - 1; i >= 0; i--) { if( component[i] != null ) { // Fix for 6607170. // We want to suppress focus change on disposal // of the focused component. But because of focus // is asynchronous, we should suppress focus change // on every component in case it receives native focus // in the process of disposal. component[i].setAutoFocusTransferOnDisposal(false); component[i].removeNotify(); component[i].setAutoFocusTransferOnDisposal(true); } } // If some of the children had focus before disposal then it still has. // Auto-transfer focus to the next (or previous) component if auto-transfer // is enabled. if (containsFocus() && KeyboardFocusManager.isAutoFocusTransferEnabledFor(this)) { if (!transferFocus(false)) { transferFocusBackward(true); } } if ( dispatcher != null ) { dispatcher.dispose(); dispatcher = null; } super.removeNotify(); } } /** * Checks if the component is contained in the component hierarchy of * this container. * @param c the component * @return true if it is an ancestor; * false otherwise. * @since JDK1.1 */ public boolean isAncestorOf(Component c) { Container p; if (c == null || ((p = c.getParent()) == null)) { return false; } while (p != null) { if (p == this) { return true; } p = p.getParent(); } return false; } /* * The following code was added to support modal JInternalFrames * Unfortunately this code has to be added here so that we can get access to * some private AWT classes like SequencedEvent. * * The native container of the LW component has this field set * to tell it that it should block Mouse events for all LW * children except for the modal component. * * In the case of nested Modal components, we store the previous * modal component in the new modal components value of modalComp; */ transient Component modalComp; transient AppContext modalAppContext; private void startLWModal() { // Store the app context on which this component is being shown. // Event dispatch thread of this app context will be sleeping until // we wake it by any event from hideAndDisposeHandler(). modalAppContext = AppContext.getAppContext(); // keep the KeyEvents from being dispatched // until the focus has been transfered long time = Toolkit.getEventQueue().getMostRecentEventTime(); Component predictedFocusOwner = (Component.isInstanceOf(this, "javax.swing.JInternalFrame")) ? ((javax.swing.JInternalFrame)(this)).getMostRecentFocusOwner() : null; if (predictedFocusOwner != null) { KeyboardFocusManager.getCurrentKeyboardFocusManager(). enqueueKeyEvents(time, predictedFocusOwner); } // We have two mechanisms for blocking: 1. If we're on the // EventDispatchThread, start a new event pump. 2. If we're // on any other thread, call wait() on the treelock. final Container nativeContainer; synchronized (getTreeLock()) { nativeContainer = getHeavyweightContainer(); if (nativeContainer.modalComp != null) { this.modalComp = nativeContainer.modalComp; nativeContainer.modalComp = this; return; } else { nativeContainer.modalComp = this; } } Runnable pumpEventsForHierarchy = new Runnable() { public void run() { EventDispatchThread dispatchThread = (EventDispatchThread)Thread.currentThread(); dispatchThread.pumpEventsForHierarchy( new Conditional() { public boolean evaluate() { return ((windowClosingException == null) && (nativeContainer.modalComp != null)) ; } }, Container.this); } }; if (EventQueue.isDispatchThread()) { SequencedEvent currentSequencedEvent = KeyboardFocusManager.getCurrentKeyboardFocusManager(). getCurrentSequencedEvent(); if (currentSequencedEvent != null) { currentSequencedEvent.dispose(); } pumpEventsForHierarchy.run(); } else { synchronized (getTreeLock()) { Toolkit.getEventQueue(). postEvent(new PeerEvent(this, pumpEventsForHierarchy, PeerEvent.PRIORITY_EVENT)); while ((windowClosingException == null) && (nativeContainer.modalComp != null)) { try { getTreeLock().wait(); } catch (InterruptedException e) { break; } } } } if (windowClosingException != null) { windowClosingException.fillInStackTrace(); throw windowClosingException; } if (predictedFocusOwner != null) { KeyboardFocusManager.getCurrentKeyboardFocusManager(). dequeueKeyEvents(time, predictedFocusOwner); } } private void stopLWModal() { synchronized (getTreeLock()) { if (modalAppContext != null) { Container nativeContainer = getHeavyweightContainer(); if(nativeContainer != null) { if (this.modalComp != null) { nativeContainer.modalComp = this.modalComp; this.modalComp = null; return; } else { nativeContainer.modalComp = null; } } // Wake up event dispatch thread on which the dialog was // initially shown SunToolkit.postEvent(modalAppContext, new PeerEvent(this, new WakingRunnable(), PeerEvent.PRIORITY_EVENT)); } EventQueue.invokeLater(new WakingRunnable()); getTreeLock().notifyAll(); } } final static class WakingRunnable implements Runnable { public void run() { } } /* End of JOptionPane support code */ /** * Returns a string representing the state of this Container. * This method is intended to be used only for debugging purposes, and the * content and format of the returned string may vary between * implementations. The returned string may be empty but may not be * null. * * @return the parameter string of this container */ protected String paramString() { String str = super.paramString(); LayoutManager layoutMgr = this.layoutMgr; if (layoutMgr != null) { str += ",layout=" + layoutMgr.getClass().getName(); } return str; } /** * Prints a listing of this container to the specified output * stream. The listing starts at the specified indentation. *

* The immediate children of the container are printed with * an indentation of indent+1. The children * of those children are printed at indent+2 * and so on. * * @param out a print stream * @param indent the number of spaces to indent * @see Component#list(java.io.PrintStream, int) * @since JDK1.0 */ public void list(PrintStream out, int indent) { super.list(out, indent); int ncomponents = this.ncomponents; Component component[] = this.component; for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null) { comp.list(out, indent+1); } } } /** * Prints out a list, starting at the specified indentation, * to the specified print writer. *

* The immediate children of the container are printed with * an indentation of indent+1. The children * of those children are printed at indent+2 * and so on. * * @param out a print writer * @param indent the number of spaces to indent * @see Component#list(java.io.PrintWriter, int) * @since JDK1.1 */ public void list(PrintWriter out, int indent) { super.list(out, indent); int ncomponents = this.ncomponents; Component component[] = this.component; for (int i = 0 ; i < ncomponents ; i++) { Component comp = component[i]; if (comp != null) { comp.list(out, indent+1); } } } /** * Sets the focus traversal keys for a given traversal operation for this * Container. *

* The default values for a Container's focus traversal keys are * implementation-dependent. Sun recommends that all implementations for a * particular native platform use the same default values. The * recommendations for Windows and Unix are listed below. These * recommendations are used in the Sun AWT implementations. * * * * * * * * * * * * * * * * * * * * * * * * * * *
IdentifierMeaningDefault
KeyboardFocusManager.FORWARD_TRAVERSAL_KEYSNormal forward keyboard traversalTAB on KEY_PRESSED, CTRL-TAB on KEY_PRESSED
KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYSNormal reverse keyboard traversalSHIFT-TAB on KEY_PRESSED, CTRL-SHIFT-TAB on KEY_PRESSED
KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYSGo up one focus traversal cyclenone
KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * Go down one focus traversal cyclenone
* * To disable a traversal key, use an empty Set; Collections.EMPTY_SET is * recommended. *

* Using the AWTKeyStroke API, client code can specify on which of two * specific KeyEvents, KEY_PRESSED or KEY_RELEASED, the focus traversal * operation will occur. Regardless of which KeyEvent is specified, * however, all KeyEvents related to the focus traversal key, including the * associated KEY_TYPED event, will be consumed, and will not be dispatched * to any Container. It is a runtime error to specify a KEY_TYPED event as * mapping to a focus traversal operation, or to map the same event to * multiple default focus traversal operations. *

* If a value of null is specified for the Set, this Container inherits the * Set from its parent. If all ancestors of this Container have null * specified for the Set, then the current KeyboardFocusManager's default * Set is used. * * @param id one of KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * @param keystrokes the Set of AWTKeyStroke for the specified operation * @see #getFocusTraversalKeys * @see KeyboardFocusManager#FORWARD_TRAVERSAL_KEYS * @see KeyboardFocusManager#BACKWARD_TRAVERSAL_KEYS * @see KeyboardFocusManager#UP_CYCLE_TRAVERSAL_KEYS * @see KeyboardFocusManager#DOWN_CYCLE_TRAVERSAL_KEYS * @throws IllegalArgumentException if id is not one of * KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS, or if keystrokes * contains null, or if any Object in keystrokes is not an * AWTKeyStroke, or if any keystroke represents a KEY_TYPED event, * or if any keystroke already maps to another focus traversal * operation for this Container * @since 1.4 * @beaninfo * bound: true */ public void setFocusTraversalKeys(int id, Set keystrokes) { if (id < 0 || id >= KeyboardFocusManager.TRAVERSAL_KEY_LENGTH) { throw new IllegalArgumentException("invalid focus traversal key identifier"); } // Don't call super.setFocusTraversalKey. The Component parameter check // does not allow DOWN_CYCLE_TRAVERSAL_KEYS, but we do. setFocusTraversalKeys_NoIDCheck(id, keystrokes); } /** * Returns the Set of focus traversal keys for a given traversal operation * for this Container. (See * setFocusTraversalKeys for a full description of each key.) *

* If a Set of traversal keys has not been explicitly defined for this * Container, then this Container's parent's Set is returned. If no Set * has been explicitly defined for any of this Container's ancestors, then * the current KeyboardFocusManager's default Set is returned. * * @param id one of KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * @return the Set of AWTKeyStrokes for the specified operation. The Set * will be unmodifiable, and may be empty. null will never be * returned. * @see #setFocusTraversalKeys * @see KeyboardFocusManager#FORWARD_TRAVERSAL_KEYS * @see KeyboardFocusManager#BACKWARD_TRAVERSAL_KEYS * @see KeyboardFocusManager#UP_CYCLE_TRAVERSAL_KEYS * @see KeyboardFocusManager#DOWN_CYCLE_TRAVERSAL_KEYS * @throws IllegalArgumentException if id is not one of * KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * @since 1.4 */ public Set getFocusTraversalKeys(int id) { if (id < 0 || id >= KeyboardFocusManager.TRAVERSAL_KEY_LENGTH) { throw new IllegalArgumentException("invalid focus traversal key identifier"); } // Don't call super.getFocusTraversalKey. The Component parameter check // does not allow DOWN_CYCLE_TRAVERSAL_KEY, but we do. return getFocusTraversalKeys_NoIDCheck(id); } /** * Returns whether the Set of focus traversal keys for the given focus * traversal operation has been explicitly defined for this Container. If * this method returns false, this Container is inheriting the * Set from an ancestor, or from the current KeyboardFocusManager. * * @param id one of KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * @return true if the the Set of focus traversal keys for the * given focus traversal operation has been explicitly defined for * this Component; false otherwise. * @throws IllegalArgumentException if id is not one of * KeyboardFocusManager.FORWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.BACKWARD_TRAVERSAL_KEYS, * KeyboardFocusManager.UP_CYCLE_TRAVERSAL_KEYS, or * KeyboardFocusManager.DOWN_CYCLE_TRAVERSAL_KEYS * @since 1.4 */ public boolean areFocusTraversalKeysSet(int id) { if (id < 0 || id >= KeyboardFocusManager.TRAVERSAL_KEY_LENGTH) { throw new IllegalArgumentException("invalid focus traversal key identifier"); } return (focusTraversalKeys != null && focusTraversalKeys[id] != null); } /** * Returns whether the specified Container is the focus cycle root of this * Container's focus traversal cycle. Each focus traversal cycle has only * a single focus cycle root and each Container which is not a focus cycle * root belongs to only a single focus traversal cycle. Containers which * are focus cycle roots belong to two cycles: one rooted at the Container * itself, and one rooted at the Container's nearest focus-cycle-root * ancestor. This method will return true for both such * Containers in this case. * * @param container the Container to be tested * @return true if the specified Container is a focus-cycle- * root of this Container; false otherwise * @see #isFocusCycleRoot() * @since 1.4 */ public boolean isFocusCycleRoot(Container container) { if (isFocusCycleRoot() && container == this) { return true; } else { return super.isFocusCycleRoot(container); } } private Container findTraversalRoot() { // I potentially have two roots, myself and my root parent // If I am the current root, then use me // If none of my parents are roots, then use me // If my root parent is the current root, then use my root parent // If neither I nor my root parent is the current root, then // use my root parent (a guess) Container currentFocusCycleRoot = KeyboardFocusManager. getCurrentKeyboardFocusManager().getCurrentFocusCycleRoot(); Container root; if (currentFocusCycleRoot == this) { root = this; } else { root = getFocusCycleRootAncestor(); if (root == null) { root = this; } } if (root != currentFocusCycleRoot) { KeyboardFocusManager.getCurrentKeyboardFocusManager(). setGlobalCurrentFocusCycleRoot(root); } return root; } final boolean containsFocus() { final Component focusOwner = KeyboardFocusManager. getCurrentKeyboardFocusManager().getFocusOwner(); return isParentOf(focusOwner); } /** * Check if this component is the child of this container or its children. * Note: this function acquires treeLock * Note: this function traverses children tree only in one Window. * @param comp a component in test, must not be null */ private boolean isParentOf(Component comp) { synchronized(getTreeLock()) { while (comp != null && comp != this && !(comp instanceof Window)) { comp = comp.getParent(); } return (comp == this); } } void clearMostRecentFocusOwnerOnHide() { boolean reset = false; Window window = null; synchronized (getTreeLock()) { window = getContainingWindow(); if (window != null) { Component comp = KeyboardFocusManager.getMostRecentFocusOwner(window); reset = ((comp == this) || isParentOf(comp)); // This synchronized should always be the second in a pair // (tree lock, KeyboardFocusManager.class) synchronized(KeyboardFocusManager.class) { Component storedComp = window.getTemporaryLostComponent(); if (isParentOf(storedComp) || storedComp == this) { window.setTemporaryLostComponent(null); } } } } if (reset) { KeyboardFocusManager.setMostRecentFocusOwner(window, null); } } void clearCurrentFocusCycleRootOnHide() { KeyboardFocusManager kfm = KeyboardFocusManager.getCurrentKeyboardFocusManager(); Container cont = kfm.getCurrentFocusCycleRoot(); if (cont == this || isParentOf(cont)) { kfm.setGlobalCurrentFocusCycleRoot(null); } } final Container getTraversalRoot() { if (isFocusCycleRoot()) { return findTraversalRoot(); } return super.getTraversalRoot(); } /** * Sets the focus traversal policy that will manage keyboard traversal of * this Container's children, if this Container is a focus cycle root. If * the argument is null, this Container inherits its policy from its focus- * cycle-root ancestor. If the argument is non-null, this policy will be * inherited by all focus-cycle-root children that have no keyboard- * traversal policy of their own (as will, recursively, their focus-cycle- * root children). *

* If this Container is not a focus cycle root, the policy will be * remembered, but will not be used or inherited by this or any other * Containers until this Container is made a focus cycle root. * * @param policy the new focus traversal policy for this Container * @see #getFocusTraversalPolicy * @see #setFocusCycleRoot * @see #isFocusCycleRoot * @since 1.4 * @beaninfo * bound: true */ public void setFocusTraversalPolicy(FocusTraversalPolicy policy) { FocusTraversalPolicy oldPolicy; synchronized (this) { oldPolicy = this.focusTraversalPolicy; this.focusTraversalPolicy = policy; } firePropertyChange("focusTraversalPolicy", oldPolicy, policy); } /** * Returns the focus traversal policy that will manage keyboard traversal * of this Container's children, or null if this Container is not a focus * cycle root. If no traversal policy has been explicitly set for this * Container, then this Container's focus-cycle-root ancestor's policy is * returned. * * @return this Container's focus traversal policy, or null if this * Container is not a focus cycle root. * @see #setFocusTraversalPolicy * @see #setFocusCycleRoot * @see #isFocusCycleRoot * @since 1.4 */ public FocusTraversalPolicy getFocusTraversalPolicy() { if (!isFocusTraversalPolicyProvider() && !isFocusCycleRoot()) { return null; } FocusTraversalPolicy policy = this.focusTraversalPolicy; if (policy != null) { return policy; } Container rootAncestor = getFocusCycleRootAncestor(); if (rootAncestor != null) { return rootAncestor.getFocusTraversalPolicy(); } else { return KeyboardFocusManager.getCurrentKeyboardFocusManager(). getDefaultFocusTraversalPolicy(); } } /** * Returns whether the focus traversal policy has been explicitly set for * this Container. If this method returns false, this * Container will inherit its focus traversal policy from an ancestor. * * @return true if the focus traversal policy has been * explicitly set for this Container; false otherwise. * @since 1.4 */ public boolean isFocusTraversalPolicySet() { return (focusTraversalPolicy != null); } /** * Sets whether this Container is the root of a focus traversal cycle. Once * focus enters a traversal cycle, typically it cannot leave it via focus * traversal unless one of the up- or down-cycle keys is pressed. Normal * traversal is limited to this Container, and all of this Container's * descendants that are not descendants of inferior focus cycle roots. Note * that a FocusTraversalPolicy may bend these restrictions, however. For * example, ContainerOrderFocusTraversalPolicy supports implicit down-cycle * traversal. *

* The alternative way to specify the traversal order of this Container's * children is to make this Container a * focus traversal policy provider. * * @param focusCycleRoot indicates whether this Container is the root of a * focus traversal cycle * @see #isFocusCycleRoot() * @see #setFocusTraversalPolicy * @see #getFocusTraversalPolicy * @see ContainerOrderFocusTraversalPolicy * @see #setFocusTraversalPolicyProvider * @since 1.4 * @beaninfo * bound: true */ public void setFocusCycleRoot(boolean focusCycleRoot) { boolean oldFocusCycleRoot; synchronized (this) { oldFocusCycleRoot = this.focusCycleRoot; this.focusCycleRoot = focusCycleRoot; } firePropertyChange("focusCycleRoot", oldFocusCycleRoot, focusCycleRoot); } /** * Returns whether this Container is the root of a focus traversal cycle. * Once focus enters a traversal cycle, typically it cannot leave it via * focus traversal unless one of the up- or down-cycle keys is pressed. * Normal traversal is limited to this Container, and all of this * Container's descendants that are not descendants of inferior focus * cycle roots. Note that a FocusTraversalPolicy may bend these * restrictions, however. For example, ContainerOrderFocusTraversalPolicy * supports implicit down-cycle traversal. * * @return whether this Container is the root of a focus traversal cycle * @see #setFocusCycleRoot * @see #setFocusTraversalPolicy * @see #getFocusTraversalPolicy * @see ContainerOrderFocusTraversalPolicy * @since 1.4 */ public boolean isFocusCycleRoot() { return focusCycleRoot; } /** * Sets whether this container will be used to provide focus * traversal policy. Container with this property as * true will be used to acquire focus traversal policy * instead of closest focus cycle root ancestor. * @param provider indicates whether this container will be used to * provide focus traversal policy * @see #setFocusTraversalPolicy * @see #getFocusTraversalPolicy * @see #isFocusTraversalPolicyProvider * @since 1.5 * @beaninfo * bound: true */ public final void setFocusTraversalPolicyProvider(boolean provider) { boolean oldProvider; synchronized(this) { oldProvider = focusTraversalPolicyProvider; focusTraversalPolicyProvider = provider; } firePropertyChange("focusTraversalPolicyProvider", oldProvider, provider); } /** * Returns whether this container provides focus traversal * policy. If this property is set to true then when * keyboard focus manager searches container hierarchy for focus * traversal policy and encounters this container before any other * container with this property as true or focus cycle roots then * its focus traversal policy will be used instead of focus cycle * root's policy. * @see #setFocusTraversalPolicy * @see #getFocusTraversalPolicy * @see #setFocusCycleRoot * @see #setFocusTraversalPolicyProvider * @return true if this container provides focus traversal * policy, false otherwise * @since 1.5 * @beaninfo * bound: true */ public final boolean isFocusTraversalPolicyProvider() { return focusTraversalPolicyProvider; } /** * Transfers the focus down one focus traversal cycle. If this Container is * a focus cycle root, then the focus owner is set to this Container's * default Component to focus, and the current focus cycle root is set to * this Container. If this Container is not a focus cycle root, then no * focus traversal operation occurs. * * @see Component#requestFocus() * @see #isFocusCycleRoot * @see #setFocusCycleRoot * @since 1.4 */ public void transferFocusDownCycle() { if (isFocusCycleRoot()) { KeyboardFocusManager.getCurrentKeyboardFocusManager(). setGlobalCurrentFocusCycleRoot(this); Component toFocus = getFocusTraversalPolicy(). getDefaultComponent(this); if (toFocus != null) { toFocus.requestFocus(CausedFocusEvent.Cause.TRAVERSAL_DOWN); } } } void preProcessKeyEvent(KeyEvent e) { Container parent = this.parent; if (parent != null) { parent.preProcessKeyEvent(e); } } void postProcessKeyEvent(KeyEvent e) { Container parent = this.parent; if (parent != null) { parent.postProcessKeyEvent(e); } } boolean postsOldMouseEvents() { return true; } /** * Sets the ComponentOrientation property of this container * and all components contained within it. * * @param o the new component orientation of this container and * the components contained within it. * @exception NullPointerException if orientation is null. * @see Component#setComponentOrientation * @see Component#getComponentOrientation * @since 1.4 */ public void applyComponentOrientation(ComponentOrientation o) { super.applyComponentOrientation(o); for (int i = 0 ; i < ncomponents ; ++i) { component[i].applyComponentOrientation(o); } } /** * Adds a PropertyChangeListener to the listener list. The listener is * registered for all bound properties of this class, including the * following: *

* Note that if this Container is inheriting a bound property, then no * event will be fired in response to a change in the inherited property. *

* If listener is null, no exception is thrown and no action is performed. * * @param listener the PropertyChangeListener to be added * * @see Component#removePropertyChangeListener * @see #addPropertyChangeListener(java.lang.String,java.beans.PropertyChangeListener) */ public void addPropertyChangeListener(PropertyChangeListener listener) { super.addPropertyChangeListener(listener); } /** * Adds a PropertyChangeListener to the listener list for a specific * property. The specified property may be user-defined, or one of the * following defaults: *

* Note that if this Container is inheriting a bound property, then no * event will be fired in response to a change in the inherited property. *

* If listener is null, no exception is thrown and no action is performed. * * @param propertyName one of the property names listed above * @param listener the PropertyChangeListener to be added * * @see #addPropertyChangeListener(java.beans.PropertyChangeListener) * @see Component#removePropertyChangeListener */ public void addPropertyChangeListener(String propertyName, PropertyChangeListener listener) { super.addPropertyChangeListener(propertyName, listener); } // Serialization support. A Container is responsible for restoring the // parent fields of its component children. /** * Container Serial Data Version. */ private int containerSerializedDataVersion = 1; /** * Serializes this Container to the specified * ObjectOutputStream. *

* * @param s the ObjectOutputStream to write * @serialData null terminated sequence of 0 or more pairs; * the pair consists of a String and Object; * the String indicates the type of object and * is one of the following: * containerListenerK indicating an * ContainerListener object; * the Container's FocusTraversalPolicy, * or null * * @see AWTEventMulticaster#save(java.io.ObjectOutputStream, java.lang.String, java.util.EventListener) * @see Container#containerListenerK * @see #readObject(ObjectInputStream) */ private void writeObject(ObjectOutputStream s) throws IOException { ObjectOutputStream.PutField f = s.putFields(); f.put("ncomponents", ncomponents); f.put("component", component); f.put("layoutMgr", layoutMgr); f.put("dispatcher", dispatcher); f.put("maxSize", maxSize); f.put("focusCycleRoot", focusCycleRoot); f.put("containerSerializedDataVersion", containerSerializedDataVersion); f.put("focusTraversalPolicyProvider", focusTraversalPolicyProvider); s.writeFields(); AWTEventMulticaster.save(s, containerListenerK, containerListener); s.writeObject(null); if (focusTraversalPolicy instanceof java.io.Serializable) { s.writeObject(focusTraversalPolicy); } else { s.writeObject(null); } } /** * Deserializes this Container from the specified * ObjectInputStream. * * * @param s the ObjectInputStream to read * @serial * @see #addContainerListener * @see #writeObject(ObjectOutputStream) */ private void readObject(ObjectInputStream s) throws ClassNotFoundException, IOException { ObjectInputStream.GetField f = s.readFields(); ncomponents = f.get("ncomponents", 0); component = (Component[])f.get("component", new Component[0]); layoutMgr = (LayoutManager)f.get("layoutMgr", null); dispatcher = (LightweightDispatcher)f.get("dispatcher", null); // Old stream. Doesn't contain maxSize among Component's fields. if (maxSize == null) { maxSize = (Dimension)f.get("maxSize", null); } focusCycleRoot = f.get("focusCycleRoot", false); containerSerializedDataVersion = f.get("containerSerializedDataVersion", 1); focusTraversalPolicyProvider = f.get("focusTraversalPolicyProvider", false); Component component[] = this.component; for(int i = 0; i < ncomponents; i++) { component[i].parent = this; adjustListeningChildren(AWTEvent.HIERARCHY_EVENT_MASK, component[i].numListening(AWTEvent.HIERARCHY_EVENT_MASK)); adjustListeningChildren(AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK, component[i].numListening( AWTEvent.HIERARCHY_BOUNDS_EVENT_MASK)); adjustDescendants(component[i].countHierarchyMembers()); } Object keyOrNull; while(null != (keyOrNull = s.readObject())) { String key = ((String)keyOrNull).intern(); if (containerListenerK == key) { addContainerListener((ContainerListener)(s.readObject())); } else { // skip value for unrecognized key s.readObject(); } } try { Object policy = s.readObject(); if (policy instanceof FocusTraversalPolicy) { focusTraversalPolicy = (FocusTraversalPolicy)policy; } } catch (java.io.OptionalDataException e) { // JDK 1.1/1.2/1.3 instances will not have this optional data. // e.eof will be true to indicate that there is no more data // available for this object. If e.eof is not true, throw the // exception as it might have been caused by reasons unrelated to // focusTraversalPolicy. if (!e.eof) { throw e; } } } /* * --- Accessibility Support --- */ /** * Inner class of Container used to provide default support for * accessibility. This class is not meant to be used directly by * application developers, but is instead meant only to be * subclassed by container developers. *

* The class used to obtain the accessible role for this object, * as well as implementing many of the methods in the * AccessibleContainer interface. * @since 1.3 */ protected class AccessibleAWTContainer extends AccessibleAWTComponent { /** * JDK1.3 serialVersionUID */ private static final long serialVersionUID = 5081320404842566097L; /** * Returns the number of accessible children in the object. If all * of the children of this object implement Accessible, * then this method should return the number of children of this object. * * @return the number of accessible children in the object */ public int getAccessibleChildrenCount() { return Container.this.getAccessibleChildrenCount(); } /** * Returns the nth Accessible child of the object. * * @param i zero-based index of child * @return the nth Accessible child of the object */ public Accessible getAccessibleChild(int i) { return Container.this.getAccessibleChild(i); } /** * Returns the Accessible child, if one exists, * contained at the local coordinate Point. * * @param p the point defining the top-left corner of the * Accessible, given in the coordinate space * of the object's parent * @return the Accessible, if it exists, * at the specified location; else null */ public Accessible getAccessibleAt(Point p) { return Container.this.getAccessibleAt(p); } protected ContainerListener accessibleContainerHandler = null; /** * Fire PropertyChange listener, if one is registered, * when children are added or removed. * @since 1.3 */ protected class AccessibleContainerHandler implements ContainerListener { public void componentAdded(ContainerEvent e) { Component c = e.getChild(); if (c != null && c instanceof Accessible) { AccessibleAWTContainer.this.firePropertyChange( AccessibleContext.ACCESSIBLE_CHILD_PROPERTY, null, ((Accessible) c).getAccessibleContext()); } } public void componentRemoved(ContainerEvent e) { Component c = e.getChild(); if (c != null && c instanceof Accessible) { AccessibleAWTContainer.this.firePropertyChange( AccessibleContext.ACCESSIBLE_CHILD_PROPERTY, ((Accessible) c).getAccessibleContext(), null); } } } /** * Adds a PropertyChangeListener to the listener list. * * @param listener the PropertyChangeListener to be added */ public void addPropertyChangeListener(PropertyChangeListener listener) { if (accessibleContainerHandler == null) { accessibleContainerHandler = new AccessibleContainerHandler(); Container.this.addContainerListener(accessibleContainerHandler); } super.addPropertyChangeListener(listener); } } // inner class AccessibleAWTContainer /** * Returns the Accessible child contained at the local * coordinate Point, if one exists. Otherwise * returns null. * * @param p the point defining the top-left corner of the * Accessible, given in the coordinate space * of the object's parent * @return the Accessible at the specified location, * if it exists; otherwise null */ Accessible getAccessibleAt(Point p) { synchronized (getTreeLock()) { if (this instanceof Accessible) { Accessible a = (Accessible)this; AccessibleContext ac = a.getAccessibleContext(); if (ac != null) { AccessibleComponent acmp; Point location; int nchildren = ac.getAccessibleChildrenCount(); for (int i=0; i < nchildren; i++) { a = ac.getAccessibleChild(i); if ((a != null)) { ac = a.getAccessibleContext(); if (ac != null) { acmp = ac.getAccessibleComponent(); if ((acmp != null) && (acmp.isShowing())) { location = acmp.getLocation(); Point np = new Point(p.x-location.x, p.y-location.y); if (acmp.contains(np)){ return a; } } } } } } return (Accessible)this; } else { Component ret = this; if (!this.contains(p.x,p.y)) { ret = null; } else { int ncomponents = this.getComponentCount(); for (int i=0; i < ncomponents; i++) { Component comp = this.getComponent(i); if ((comp != null) && comp.isShowing()) { Point location = comp.getLocation(); if (comp.contains(p.x-location.x,p.y-location.y)) { ret = comp; } } } } if (ret instanceof Accessible) { return (Accessible) ret; } } return null; } } /** * Returns the number of accessible children in the object. If all * of the children of this object implement Accessible, * then this method should return the number of children of this object. * * @return the number of accessible children in the object */ int getAccessibleChildrenCount() { synchronized (getTreeLock()) { int count = 0; Component[] children = this.getComponents(); for (int i = 0; i < children.length; i++) { if (children[i] instanceof Accessible) { count++; } } return count; } } /** * Returns the nth Accessible child of the object. * * @param i zero-based index of child * @return the nth Accessible child of the object */ Accessible getAccessibleChild(int i) { synchronized (getTreeLock()) { Component[] children = this.getComponents(); int count = 0; for (int j = 0; j < children.length; j++) { if (children[j] instanceof Accessible) { if (count == i) { return (Accessible) children[j]; } else { count++; } } } return null; } } // ************************** MIXING CODE ******************************* final void increaseComponentCount(Component c) { synchronized (getTreeLock()) { if (!c.isDisplayable()) { throw new IllegalStateException( "Peer does not exist while invoking the increaseComponentCount() method" ); } int addHW = 0; int addLW = 0; if (c instanceof Container) { addLW = ((Container)c).numOfLWComponents; addHW = ((Container)c).numOfHWComponents; } if (c.isLightweight()) { addLW++; } else { addHW++; } for (Container cont = this; cont != null; cont = cont.getContainer()) { cont.numOfLWComponents += addLW; cont.numOfHWComponents += addHW; } } } final void decreaseComponentCount(Component c) { synchronized (getTreeLock()) { if (!c.isDisplayable()) { throw new IllegalStateException( "Peer does not exist while invoking the decreaseComponentCount() method" ); } int subHW = 0; int subLW = 0; if (c instanceof Container) { subLW = ((Container)c).numOfLWComponents; subHW = ((Container)c).numOfHWComponents; } if (c.isLightweight()) { subLW++; } else { subHW++; } for (Container cont = this; cont != null; cont = cont.getContainer()) { cont.numOfLWComponents -= subLW; cont.numOfHWComponents -= subHW; } } } private int getTopmostComponentIndex() { checkTreeLock(); if (getComponentCount() > 0) { return 0; } return -1; } private int getBottommostComponentIndex() { checkTreeLock(); if (getComponentCount() > 0) { return getComponentCount() - 1; } return -1; } final void recursiveSubtractAndApplyShape(Region shape) { recursiveSubtractAndApplyShape(shape, getTopmostComponentIndex(), getBottommostComponentIndex()); } final void recursiveSubtractAndApplyShape(Region shape, int fromZorder) { recursiveSubtractAndApplyShape(shape, fromZorder, getBottommostComponentIndex()); } final void recursiveSubtractAndApplyShape(Region shape, int fromZorder, int toZorder) { checkTreeLock(); if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this + "; shape=" + shape + "; fromZ=" + fromZorder + "; toZ=" + toZorder); } if (fromZorder == -1) { return; } for (int index = fromZorder; index <= toZorder; index++) { Component comp = getComponent(index); if (!comp.isLightweight()) { comp.subtractAndApplyShape(shape); } else if (comp instanceof Container && ((Container)comp).hasHeavyweightDescendants() && comp.isShowing()) { ((Container)comp).recursiveSubtractAndApplyShape(shape); } } } final void recursiveApplyCurrentShape() { recursiveApplyCurrentShape(getTopmostComponentIndex(), getBottommostComponentIndex()); } final void recursiveApplyCurrentShape(int fromZorder) { recursiveApplyCurrentShape(fromZorder, getBottommostComponentIndex()); } final void recursiveApplyCurrentShape(int fromZorder, int toZorder) { checkTreeLock(); if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this + "; fromZ=" + fromZorder + "; toZ=" + toZorder); } if (fromZorder == -1) { return; } for (int index = fromZorder; index <= toZorder; index++) { Component comp = getComponent(index); if (!comp.isLightweight()) { comp.applyCurrentShape(); } else if (comp instanceof Container && ((Container)comp).hasHeavyweightDescendants()) { ((Container)comp).recursiveApplyCurrentShape(); } } } private void recursiveShowHeavyweightChildren() { if (!hasHeavyweightDescendants() || !isVisible()) { return; } for (int index = 0; index < getComponentCount(); index++) { Component comp = getComponent(index); if (comp.isLightweight()) { if (comp instanceof Container) { ((Container)comp).recursiveShowHeavyweightChildren(); } } else { if (comp.isVisible()) { ComponentPeer peer = comp.getPeer(); if (peer != null) { peer.show(); } } } } } private void recursiveHideHeavyweightChildren() { if (!hasHeavyweightDescendants()) { return; } for (int index = 0; index < getComponentCount(); index++) { Component comp = getComponent(index); if (comp.isLightweight()) { if (comp instanceof Container) { ((Container)comp).recursiveHideHeavyweightChildren(); } } else { if (comp.isVisible()) { ComponentPeer peer = comp.getPeer(); if (peer != null) { peer.hide(); } } } } } private void recursiveRelocateHeavyweightChildren(Point origin) { for (int index = 0; index < getComponentCount(); index++) { Component comp = getComponent(index); if (comp.isLightweight()) { if (comp instanceof Container && ((Container)comp).hasHeavyweightDescendants()) { final Point newOrigin = new Point(origin); newOrigin.translate(comp.getX(), comp.getY()); ((Container)comp).recursiveRelocateHeavyweightChildren(newOrigin); } } else { ComponentPeer peer = comp.getPeer(); if (peer != null) { peer.setBounds(origin.x + comp.getX(), origin.y + comp.getY(), comp.getWidth(), comp.getHeight(), ComponentPeer.SET_LOCATION); } } } } /* * Consider the heavyweight container hides or shows the HW descendants * automatically. Therefore we care of LW containers' visibility only. */ private boolean isRecursivelyVisibleUpToHeavyweightContainer() { if (!isLightweight()) { return true; } return isVisible() && (getContainer() == null || getContainer().isRecursivelyVisibleUpToHeavyweightContainer()); } @Override void mixOnShowing() { synchronized (getTreeLock()) { if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this); } boolean isLightweight = isLightweight(); if (isLightweight && isRecursivelyVisibleUpToHeavyweightContainer()) { recursiveShowHeavyweightChildren(); } if (!isLightweight || (isLightweight && hasHeavyweightDescendants())) { recursiveApplyCurrentShape(); } super.mixOnShowing(); } } @Override void mixOnHiding(boolean isLightweight) { synchronized (getTreeLock()) { if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this + "; isLightweight=" + isLightweight); } if (isLightweight) { recursiveHideHeavyweightChildren(); } super.mixOnHiding(isLightweight); } } @Override void mixOnReshaping() { synchronized (getTreeLock()) { if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this); } if (isLightweight() && hasHeavyweightDescendants()) { final Point origin = new Point(getX(), getY()); for (Container cont = getContainer(); cont != null && cont.isLightweight(); cont = cont.getContainer()) { origin.translate(cont.getX(), cont.getY()); } recursiveRelocateHeavyweightChildren(origin); } super.mixOnReshaping(); } } @Override void mixOnZOrderChanging(int oldZorder, int newZorder) { synchronized (getTreeLock()) { if (mixingLog.isLoggable(Level.FINE)) { mixingLog.fine("this = " + this + "; oldZ=" + oldZorder + "; newZ=" + newZorder); } boolean becameHigher = newZorder < oldZorder; if (becameHigher && isLightweight() && hasHeavyweightDescendants()) { recursiveApplyCurrentShape(); } super.mixOnZOrderChanging(oldZorder, newZorder); } } // ****************** END OF MIXING CODE ******************************** } /** * Class to manage the dispatching of MouseEvents to the lightweight descendants * and SunDropTargetEvents to both lightweight and heavyweight descendants * contained by a native container. * * NOTE: the class name is not appropriate anymore, but we cannot change it * because we must keep serialization compatibility. * * @author Timothy Prinzing */ class LightweightDispatcher implements java.io.Serializable, AWTEventListener { /* * JDK 1.1 serialVersionUID */ private static final long serialVersionUID = 5184291520170872969L; /* * Our own mouse event for when we're dragged over from another hw * container */ private static final int LWD_MOUSE_DRAGGED_OVER = 1500; private static final Logger eventLog = Logger.getLogger("java.awt.event.LightweightDispatcher"); LightweightDispatcher(Container nativeContainer) { this.nativeContainer = nativeContainer; mouseEventTarget = null; eventMask = 0; } /* * Clean up any resources allocated when dispatcher was created; * should be called from Container.removeNotify */ void dispose() { //System.out.println("Disposing lw dispatcher"); stopListeningForOtherDrags(); mouseEventTarget = null; } /** * Enables events to subcomponents. */ void enableEvents(long events) { eventMask |= events; } /** * Dispatches an event to a sub-component if necessary, and * returns whether or not the event was forwarded to a * sub-component. * * @param e the event */ boolean dispatchEvent(AWTEvent e) { boolean ret = false; /* * Fix for BugTraq Id 4389284. * Dispatch SunDropTargetEvents regardless of eventMask value. * Do not update cursor on dispatching SunDropTargetEvents. */ if (e instanceof SunDropTargetEvent) { SunDropTargetEvent sdde = (SunDropTargetEvent) e; ret = processDropTargetEvent(sdde); } else { if (e instanceof MouseEvent && (eventMask & MOUSE_MASK) != 0) { MouseEvent me = (MouseEvent) e; ret = processMouseEvent(me); } if (e.getID() == MouseEvent.MOUSE_MOVED) { nativeContainer.updateCursorImmediately(); } } return ret; } /* This method effectively returns whether or not a mouse button was down * just BEFORE the event happened. A better method name might be * wasAMouseButtonDownBeforeThisEvent(). */ private boolean isMouseGrab(MouseEvent e) { int modifiers = e.getModifiersEx(); if(e.getID() == MouseEvent.MOUSE_PRESSED || e.getID() == MouseEvent.MOUSE_RELEASED) { switch (e.getButton()) { case MouseEvent.BUTTON1: modifiers ^= InputEvent.BUTTON1_DOWN_MASK; break; case MouseEvent.BUTTON2: modifiers ^= InputEvent.BUTTON2_DOWN_MASK; break; case MouseEvent.BUTTON3: modifiers ^= InputEvent.BUTTON3_DOWN_MASK; break; } } /* modifiers now as just before event */ return ((modifiers & (InputEvent.BUTTON1_DOWN_MASK | InputEvent.BUTTON2_DOWN_MASK | InputEvent.BUTTON3_DOWN_MASK)) != 0); } /** * This method attempts to distribute a mouse event to a lightweight * component. It tries to avoid doing any unnecessary probes down * into the component tree to minimize the overhead of determining * where to route the event, since mouse movement events tend to * come in large and frequent amounts. */ private boolean processMouseEvent(MouseEvent e) { int id = e.getID(); Component mouseOver = // sensitive to mouse events nativeContainer.getMouseEventTarget(e.getX(), e.getY(), Container.INCLUDE_SELF); trackMouseEnterExit(mouseOver, e); // 4508327 : MOUSE_CLICKED should only go to the recipient of // the accompanying MOUSE_PRESSED, so don't reset mouseEventTarget on a // MOUSE_CLICKED. if (!isMouseGrab(e) && id != MouseEvent.MOUSE_CLICKED) { mouseEventTarget = (mouseOver != nativeContainer) ? mouseOver: null; } if (mouseEventTarget != null) { switch (id) { case MouseEvent.MOUSE_ENTERED: case MouseEvent.MOUSE_EXITED: break; case MouseEvent.MOUSE_PRESSED: retargetMouseEvent(mouseEventTarget, id, e); break; case MouseEvent.MOUSE_RELEASED: retargetMouseEvent(mouseEventTarget, id, e); break; case MouseEvent.MOUSE_CLICKED: // 4508327: MOUSE_CLICKED should never be dispatched to a Component // other than that which received the MOUSE_PRESSED event. If the // mouse is now over a different Component, don't dispatch the event. // The previous fix for a similar problem was associated with bug // 4155217. if (mouseOver == mouseEventTarget) { retargetMouseEvent(mouseOver, id, e); } break; case MouseEvent.MOUSE_MOVED: retargetMouseEvent(mouseEventTarget, id, e); break; case MouseEvent.MOUSE_DRAGGED: if (isMouseGrab(e)) { retargetMouseEvent(mouseEventTarget, id, e); } break; case MouseEvent.MOUSE_WHEEL: // This may send it somewhere that doesn't have MouseWheelEvents // enabled. In this case, Component.dispatchEventImpl() will // retarget the event to a parent that DOES have the events enabled. if (eventLog.isLoggable(Level.FINEST) && (mouseOver != null)) { eventLog.log(Level.FINEST, "retargeting mouse wheel to " + mouseOver.getName() + ", " + mouseOver.getClass()); } retargetMouseEvent(mouseOver, id, e); break; } e.consume(); } return e.isConsumed(); } private boolean processDropTargetEvent(SunDropTargetEvent e) { int id = e.getID(); int x = e.getX(); int y = e.getY(); /* * Fix for BugTraq ID 4395290. * It is possible that SunDropTargetEvent's Point is outside of the * native container bounds. In this case we truncate coordinates. */ if (!nativeContainer.contains(x, y)) { final Dimension d = nativeContainer.getSize(); if (d.width <= x) { x = d.width - 1; } else if (x < 0) { x = 0; } if (d.height <= y) { y = d.height - 1; } else if (y < 0) { y = 0; } } Component mouseOver = // not necessarily sensitive to mouse events nativeContainer.getDropTargetEventTarget(x, y, Container.INCLUDE_SELF); trackMouseEnterExit(mouseOver, e); if (mouseOver != nativeContainer && mouseOver != null) { switch (id) { case SunDropTargetEvent.MOUSE_ENTERED: case SunDropTargetEvent.MOUSE_EXITED: break; default: retargetMouseEvent(mouseOver, id, e); e.consume(); break; } } return e.isConsumed(); } /* * Generates enter/exit events as mouse moves over lw components * @param targetOver Target mouse is over (including native container) * @param e Mouse event in native container */ private void trackMouseEnterExit(Component targetOver, MouseEvent e) { Component targetEnter = null; int id = e.getID(); if (e instanceof SunDropTargetEvent && id == MouseEvent.MOUSE_ENTERED && isMouseInNativeContainer == true) { // This can happen if a lightweight component which initiated the // drag has an associated drop target. MOUSE_ENTERED comes when the // mouse is in the native container already. To propagate this event // properly we should null out targetLastEntered. targetLastEntered = null; } else if ( id != MouseEvent.MOUSE_EXITED && id != MouseEvent.MOUSE_DRAGGED && id != LWD_MOUSE_DRAGGED_OVER && isMouseInNativeContainer == false ) { // any event but an exit or drag means we're in the native container isMouseInNativeContainer = true; startListeningForOtherDrags(); } else if ( id == MouseEvent.MOUSE_EXITED ) { isMouseInNativeContainer = false; stopListeningForOtherDrags(); } if (isMouseInNativeContainer) { targetEnter = targetOver; } if (targetLastEntered == targetEnter) { return; } if (targetLastEntered != null) { retargetMouseEvent(targetLastEntered, MouseEvent.MOUSE_EXITED, e); } if (id == MouseEvent.MOUSE_EXITED) { // consume native exit event if we generate one e.consume(); } if (targetEnter != null) { retargetMouseEvent(targetEnter, MouseEvent.MOUSE_ENTERED, e); } if (id == MouseEvent.MOUSE_ENTERED) { // consume native enter event if we generate one e.consume(); } targetLastEntered = targetEnter; } /* * Listens to global mouse drag events so even drags originating * from other heavyweight containers will generate enter/exit * events in this container */ private void startListeningForOtherDrags() { //System.out.println("Adding AWTEventListener"); java.security.AccessController.doPrivileged( new java.security.PrivilegedAction() { public Object run() { nativeContainer.getToolkit().addAWTEventListener( LightweightDispatcher.this, AWTEvent.MOUSE_EVENT_MASK | AWTEvent.MOUSE_MOTION_EVENT_MASK); return null; } } ); } private void stopListeningForOtherDrags() { //System.out.println("Removing AWTEventListener"); java.security.AccessController.doPrivileged( new java.security.PrivilegedAction() { public Object run() { nativeContainer.getToolkit().removeAWTEventListener(LightweightDispatcher.this); return null; } } ); } /* * (Implementation of AWTEventListener) * Listen for drag events posted in other hw components so we can * track enter/exit regardless of where a drag originated */ public void eventDispatched(AWTEvent e) { boolean isForeignDrag = (e instanceof MouseEvent) && !(e instanceof SunDropTargetEvent) && (e.id == MouseEvent.MOUSE_DRAGGED) && (e.getSource() != nativeContainer); if (!isForeignDrag) { // only interested in drags from other hw components return; } MouseEvent srcEvent = (MouseEvent)e; MouseEvent me; synchronized (nativeContainer.getTreeLock()) { Component srcComponent = srcEvent.getComponent(); // component may have disappeared since drag event posted // (i.e. Swing hierarchical menus) if ( !srcComponent.isShowing() ) { return; } // see 5083555 // check if srcComponent is in any modal blocked window Component c = nativeContainer; while ((c != null) && !(c instanceof Window)) { c = c.getParent_NoClientCode(); } if ((c == null) || ((Window)c).isModalBlocked()) { return; } // // create an internal 'dragged-over' event indicating // we are being dragged over from another hw component // me = new MouseEvent(nativeContainer, LWD_MOUSE_DRAGGED_OVER, srcEvent.getWhen(), srcEvent.getModifiersEx() | srcEvent.getModifiers(), srcEvent.getX(), srcEvent.getY(), srcEvent.getXOnScreen(), srcEvent.getYOnScreen(), srcEvent.getClickCount(), srcEvent.isPopupTrigger(), srcEvent.getButton()); ((AWTEvent)srcEvent).copyPrivateDataInto(me); // translate coordinates to this native container final Point ptSrcOrigin = srcComponent.getLocationOnScreen(); if (AppContext.getAppContext() != nativeContainer.appContext) { final MouseEvent mouseEvent = me; Runnable r = new Runnable() { public void run() { if (!nativeContainer.isShowing() ) { return; } Point ptDstOrigin = nativeContainer.getLocationOnScreen(); mouseEvent.translatePoint(ptSrcOrigin.x - ptDstOrigin.x, ptSrcOrigin.y - ptDstOrigin.y ); Component targetOver = nativeContainer.getMouseEventTarget(mouseEvent.getX(), mouseEvent.getY(), Container.INCLUDE_SELF); trackMouseEnterExit(targetOver, mouseEvent); } }; SunToolkit.executeOnEventHandlerThread(nativeContainer, r); return; } else { if (!nativeContainer.isShowing() ) { return; } Point ptDstOrigin = nativeContainer.getLocationOnScreen(); me.translatePoint( ptSrcOrigin.x - ptDstOrigin.x, ptSrcOrigin.y - ptDstOrigin.y ); } } //System.out.println("Track event: " + me); // feed the 'dragged-over' event directly to the enter/exit // code (not a real event so don't pass it to dispatchEvent) Component targetOver = nativeContainer.getMouseEventTarget(me.getX(), me.getY(), Container.INCLUDE_SELF); trackMouseEnterExit(targetOver, me); } /** * Sends a mouse event to the current mouse event recipient using * the given event (sent to the windowed host) as a srcEvent. If * the mouse event target is still in the component tree, the * coordinates of the event are translated to those of the target. * If the target has been removed, we don't bother to send the * message. */ void retargetMouseEvent(Component target, int id, MouseEvent e) { if (target == null) { return; // mouse is over another hw component or target is disabled } int x = e.getX(), y = e.getY(); Component component; for(component = target; component != null && component != nativeContainer; component = component.getParent()) { x -= component.x; y -= component.y; } MouseEvent retargeted; if (component != null) { if (e instanceof SunDropTargetEvent) { retargeted = new SunDropTargetEvent(target, id, x, y, ((SunDropTargetEvent)e).getDispatcher()); } else if (id == MouseEvent.MOUSE_WHEEL) { retargeted = new MouseWheelEvent(target, id, e.getWhen(), e.getModifiersEx() | e.getModifiers(), x, y, e.getXOnScreen(), e.getYOnScreen(), e.getClickCount(), e.isPopupTrigger(), ((MouseWheelEvent)e).getScrollType(), ((MouseWheelEvent)e).getScrollAmount(), ((MouseWheelEvent)e).getWheelRotation(), ((MouseWheelEvent)e).getPreciseWheelRotation()); } else { retargeted = new MouseEvent(target, id, e.getWhen(), e.getModifiersEx() | e.getModifiers(), x, y, e.getXOnScreen(), e.getYOnScreen(), e.getClickCount(), e.isPopupTrigger(), e.getButton()); } ((AWTEvent)e).copyPrivateDataInto(retargeted); if (target == nativeContainer) { // avoid recursively calling LightweightDispatcher... ((Container)target).dispatchEventToSelf(retargeted); } else { assert AppContext.getAppContext() == target.appContext; if (nativeContainer.modalComp != null) { if (((Container)nativeContainer.modalComp).isAncestorOf(target)) { target.dispatchEvent(retargeted); } else { e.consume(); } } else { target.dispatchEvent(retargeted); } } } } // --- member variables ------------------------------- /** * The windowed container that might be hosting events for * subcomponents. */ private Container nativeContainer; /** * This variable is not used, but kept for serialization compatibility */ private Component focus; /** * The current subcomponent being hosted by this windowed * component that has events being forwarded to it. If this * is null, there are currently no events being forwarded to * a subcomponent. */ private transient Component mouseEventTarget; /** * The last component entered */ private transient Component targetLastEntered; /** * Is the mouse over the native container */ private transient boolean isMouseInNativeContainer = false; /** * This variable is not used, but kept for serialization compatibility */ private Cursor nativeCursor; /** * The event mask for contained lightweight components. Lightweight * components need a windowed container to host window-related * events. This separate mask indicates events that have been * requested by contained lightweight components without effecting * the mask of the windowed component itself. */ private long eventMask; /** * The kind of events routed to lightweight components from windowed * hosts. */ private static final long PROXY_EVENT_MASK = AWTEvent.FOCUS_EVENT_MASK | AWTEvent.KEY_EVENT_MASK | AWTEvent.MOUSE_EVENT_MASK | AWTEvent.MOUSE_MOTION_EVENT_MASK | AWTEvent.MOUSE_WHEEL_EVENT_MASK; private static final long MOUSE_MASK = AWTEvent.MOUSE_EVENT_MASK | AWTEvent.MOUSE_MOTION_EVENT_MASK | AWTEvent.MOUSE_WHEEL_EVENT_MASK; }