FileDocCategorySizeDatePackage
ParentNode.javaAPI DocJava SE 5 API38343Fri Aug 26 14:55:44 BST 2005com.sun.org.apache.xerces.internal.dom

ParentNode

public abstract class ParentNode extends ChildNode
ParentNode inherits from ChildNode and adds the capability of having child nodes. Not every node in the DOM can have children, so only nodes that can should inherit from this class and pay the price for it.

ParentNode, just like NodeImpl, also implements NodeList, so it can return itself in response to the getChildNodes() query. This eliminiates the need for a separate ChildNodeList object. Note that this is an IMPLEMENTATION DETAIL; applications should _never_ assume that this identity exists. On the other hand, subclasses may need to override this, in case of conflicting names. This is the case for the classes HTMLSelectElementImpl and HTMLFormElementImpl of the HTML DOM.

While we have a direct reference to the first child, the last child is stored as the previous sibling of the first child. First child nodes are marked as being so, and getNextSibling hides this fact.

Note: Not all parent nodes actually need to also be a child. At some point we used to have ParentNode inheriting from NodeImpl and another class called ChildAndParentNode that inherited from ChildNode. But due to the lack of multiple inheritance a lot of code had to be duplicated which led to a maintenance nightmare. At the same time only a few nodes (Document, DocumentFragment, Entity, and Attribute) cannot be a child so the gain in memory wasn't really worth it. The only type for which this would be the case is Attribute, but we deal with there in another special way, so this is not applicable.

This class doesn't directly support mutation events, however, it notifies the document when mutations are performed so that the document class do so.

WARNING: Some of the code here is partially duplicated in AttrImpl, be careful to keep these two classes in sync!

author
Arnaud Le Hors, IBM
author
Joe Kesselman, IBM
author
Andy Clark, IBM
version
$Id: ParentNode.java,v 1.41 2004/02/10 17:09:45 elena Exp $

Fields Summary
static final long
serialVersionUID
Serialization version.
protected CoreDocumentImpl
ownerDocument
Owner document.
protected ChildNode
firstChild
First child.
protected transient NodeListCache
fNodeListCache
NodeList cache
Constructors Summary
protected ParentNode(CoreDocumentImpl ownerDocument)
No public constructor; only subclasses of ParentNode should be instantiated, and those normally via a Document's factory methods


    //
    // Constructors
    //

                           
       
        super(ownerDocument);
        this.ownerDocument = ownerDocument;
    
public ParentNode()
Constructor for serialization.

Methods Summary
voidcheckNormalizationAfterInsert(com.sun.org.apache.xerces.internal.dom.ChildNode insertedChild)
Checks the normalized state of this node after inserting a child. If the inserted child causes this node to be unnormalized, then this node is flagged accordingly. The conditions for changing the normalized state are:
  • The inserted child is a text node and one of its adjacent siblings is also a text node.
  • The inserted child is is itself unnormalized.

param
insertedChild the child node that was inserted into this node
throws
NullPointerException if the inserted child is null

        // See if insertion caused this node to be unnormalized.
        if (insertedChild.getNodeType() == Node.TEXT_NODE) {
            ChildNode prev = insertedChild.previousSibling();
            ChildNode next = insertedChild.nextSibling;
            // If an adjacent sibling of the new child is a text node,
            // flag this node as unnormalized.
            if ((prev != null && prev.getNodeType() == Node.TEXT_NODE) ||
                (next != null && next.getNodeType() == Node.TEXT_NODE)) {
                isNormalized(false);
            }
        }
        else {
            // If the new child is not normalized,
            // then this node is inherently not normalized.
            if (!insertedChild.isNormalized()) {
                isNormalized(false);
            }
        }
    
voidcheckNormalizationAfterRemove(com.sun.org.apache.xerces.internal.dom.ChildNode previousSibling)
Checks the normalized of this node after removing a child. If the removed child causes this node to be unnormalized, then this node is flagged accordingly. The conditions for changing the normalized state are:
  • The removed child had two adjacent siblings that were text nodes.

param
previousSibling the previous sibling of the removed child, or null

        // See if removal caused this node to be unnormalized.
        // If the adjacent siblings of the removed child were both text nodes,
        // flag this node as unnormalized.
        if (previousSibling != null &&
            previousSibling.getNodeType() == Node.TEXT_NODE) {

            ChildNode next = previousSibling.nextSibling;
            if (next != null && next.getNodeType() == Node.TEXT_NODE) {
                isNormalized(false);
            }
        }
    
public org.w3c.dom.NodecloneNode(boolean deep)
Returns a duplicate of a given node. You can consider this a generic "copy constructor" for nodes. The newly returned object should be completely independent of the source object's subtree, so changes in one after the clone has been made will not affect the other.

Example: Cloning a Text node will copy both the node and the text it contains.

Example: Cloning something that has children -- Element or Attr, for example -- will _not_ clone those children unless a "deep clone" has been requested. A shallow clone of an Attr node will yield an empty Attr of the same name.

NOTE: Clones will always be read/write, even if the node being cloned is read-only, to permit applications using only the DOM API to obtain editable copies of locked portions of the tree.

    	
        if (needsSyncChildren()) {
            synchronizeChildren();
        }
    	ParentNode newnode = (ParentNode) super.cloneNode(deep);

        // set owner document
        newnode.ownerDocument = ownerDocument;

    	// Need to break the association w/ original kids
    	newnode.firstChild      = null;

        // invalidate cache for children NodeList
        newnode.fNodeListCache = null;

        // Then, if deep, clone the kids too.
    	if (deep) {
            for (ChildNode child = firstChild;
                 child != null;
                 child = child.nextSibling) {
                newnode.appendChild(child.cloneNode(true));
            }
        }

    	return newnode;

    
public org.w3c.dom.NodeListgetChildNodes()
Obtain a NodeList enumerating all children of this node. If there are none, an (initially) empty NodeList is returned.

NodeLists are "live"; as children are added/removed the NodeList will immediately reflect those changes. Also, the NodeList refers to the actual nodes, so changes to those nodes made via the DOM tree will be reflected in the NodeList and vice versa.

In this implementation, Nodes implement the NodeList interface and provide their own getChildNodes() support. Other DOMs may solve this differently.


        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        return this;

    
protected final org.w3c.dom.NodeListgetChildNodesUnoptimized()
Create a NodeList to access children that is use by subclass elements that have methods named getLength() or item(int). ChildAndParentNode optimizes getChildNodes() by implementing NodeList itself. However if a subclass Element implements methods with the same name as the NodeList methods, they will override the actually methods in this class.

To use this method, the subclass should implement getChildNodes() and have it call this method. The resulting NodeList instance maybe shared and cached in a transient field, but the cached value must be cleared if the node is cloned.

        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        return new NodeList() {
                /**
                 * @see NodeList.getLength()
                 */
                public int getLength() {
                    return nodeListGetLength();
                } // getLength():int
                
                /**
                 * @see NodeList.item(int)
                 */
                public Node item(int index) {
                    return nodeListItem(index);
                } // item(int):Node
            };
    
public org.w3c.dom.NodegetFirstChild()
The first child of this Node, or null if none.


        if (needsSyncChildren()) {
            synchronizeChildren();
        }
    	return firstChild;

    
public org.w3c.dom.NodegetLastChild()
The last child of this Node, or null if none.


        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        return lastChild();

    
public intgetLength()
NodeList method: Count the immediate children of this node

return
int

        return nodeListGetLength();
    
public org.w3c.dom.DocumentgetOwnerDocument()
Find the Document that this Node belongs to (the document in whose context the Node was created). The Node may or may not currently be part of that Document's actual contents.

        return ownerDocument;
    
public java.lang.StringgetTextContent()

        Node child = getFirstChild();
        if (child != null) {
            Node next = child.getNextSibling();
            if (next == null) {
                return hasTextContent(child) ? ((NodeImpl) child).getTextContent() : "";
            }
            if (fBufferStr == null){
                fBufferStr = new StringBuffer();
            }
            else {
                fBufferStr.setLength(0);
            }
            getTextContent(fBufferStr);
            return fBufferStr.toString();
        }
        return "";
    
voidgetTextContent(java.lang.StringBuffer buf)

        Node child = getFirstChild();
        while (child != null) {
            if (hasTextContent(child)) {
                ((NodeImpl) child).getTextContent(buf);
            }
            child = child.getNextSibling();
        }
    
public booleanhasChildNodes()
Test whether this node has any children. Convenience shorthand for (Node.getFirstChild()!=null)

        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        return firstChild != null;
    
final booleanhasTextContent(org.w3c.dom.Node child)

        return child.getNodeType() != Node.COMMENT_NODE &&
            child.getNodeType() != Node.PROCESSING_INSTRUCTION_NODE &&
            (child.getNodeType() != Node.TEXT_NODE ||
             ((TextImpl) child).isIgnorableWhitespace() == false);
    
public org.w3c.dom.NodeinsertBefore(org.w3c.dom.Node newChild, org.w3c.dom.Node refChild)
Move one or more node(s) to our list of children. Note that this implicitly removes them from their previous parent.

param
newChild The Node to be moved to our subtree. As a convenience feature, inserting a DocumentNode will instead insert all its children.
param
refChild Current child which newChild should be placed immediately before. If refChild is null, the insertion occurs after all existing Nodes, like appendChild().
return
newChild, in its new state (relocated, or emptied in the case of DocumentNode.)
throws
DOMException(HIERARCHY_REQUEST_ERR) if newChild is of a type that shouldn't be a child of this node, or if newChild is an ancestor of this node.
throws
DOMException(WRONG_DOCUMENT_ERR) if newChild has a different owner document than we do.
throws
DOMException(NOT_FOUND_ERR) if refChild is not a child of this node.
throws
DOMException(NO_MODIFICATION_ALLOWED_ERR) if this node is read-only.

        // Tail-call; optimizer should be able to do good things with.
        return internalInsertBefore(newChild, refChild, false);
    
org.w3c.dom.NodeinternalInsertBefore(org.w3c.dom.Node newChild, org.w3c.dom.Node refChild, boolean replace)
NON-DOM INTERNAL: Within DOM actions,we sometimes need to be able to control which mutation events are spawned. This version of the insertBefore operation allows us to do so. It is not intended for use by application programs.


        boolean errorChecking = ownerDocument.errorChecking;

        if (newChild.getNodeType() == Node.DOCUMENT_FRAGMENT_NODE) {
            // SLOW BUT SAFE: We could insert the whole subtree without
            // juggling so many next/previous pointers. (Wipe out the
            // parent's child-list, patch the parent pointers, set the
            // ends of the list.) But we know some subclasses have special-
            // case behavior they add to insertBefore(), so we don't risk it.
            // This approch also takes fewer bytecodes.

            // NOTE: If one of the children is not a legal child of this
            // node, throw HIERARCHY_REQUEST_ERR before _any_ of the children
            // have been transferred. (Alternative behaviors would be to
            // reparent up to the first failure point or reparent all those
            // which are acceptable to the target node, neither of which is
            // as robust. PR-DOM-0818 isn't entirely clear on which it
            // recommends?????

            // No need to check kids for right-document; if they weren't,
            // they wouldn't be kids of that DocFrag.
            if (errorChecking) {
                for (Node kid = newChild.getFirstChild(); // Prescan
                     kid != null; kid = kid.getNextSibling()) {

                    if (!ownerDocument.isKidOK(this, kid)) {
                        throw new DOMException(
                              DOMException.HIERARCHY_REQUEST_ERR, 
                              DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "HIERARCHY_REQUEST_ERR", null));
                    }
                }
            }

            while (newChild.hasChildNodes()) {
                insertBefore(newChild.getFirstChild(), refChild);
            }
            return newChild;
        }

        if (newChild == refChild) {
            // stupid case that must be handled as a no-op triggering events...
            refChild = refChild.getNextSibling();
            removeChild(newChild);
            insertBefore(newChild, refChild);
            return newChild;
        }

        if (needsSyncChildren()) {
            synchronizeChildren();
        }

        if (errorChecking) {
            if (isReadOnly()) {
                throw new DOMException(
                              DOMException.NO_MODIFICATION_ALLOWED_ERR, 
                              DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "NO_MODIFICATION_ALLOWED_ERR", null));
            }
            if (newChild.getOwnerDocument() != ownerDocument && newChild != ownerDocument) {
                throw new DOMException(DOMException.WRONG_DOCUMENT_ERR, 
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null));
            }
            if (!ownerDocument.isKidOK(this, newChild)) {
                throw new DOMException(DOMException.HIERARCHY_REQUEST_ERR, 
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "HIERARCHY_REQUEST_ERR", null));
            }
            // refChild must be a child of this node (or null)
            if (refChild != null && refChild.getParentNode() != this) {
                throw new DOMException(DOMException.NOT_FOUND_ERR,
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "NOT_FOUND_ERR", null));
            }

            // Prevent cycles in the tree
            // newChild cannot be ancestor of this Node,
            // and actually cannot be this
            boolean treeSafe = true;
            for (NodeImpl a = this; treeSafe && a != null; a = a.parentNode())
            {
                treeSafe = newChild != a;
            }
            if(!treeSafe) {
                throw new DOMException(DOMException.HIERARCHY_REQUEST_ERR, 
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "HIERARCHY_REQUEST_ERR", null));
            }
        }

        // notify document
        ownerDocument.insertingNode(this, replace);

        // Convert to internal type, to avoid repeated casting
        ChildNode newInternal = (ChildNode)newChild;

        Node oldparent = newInternal.parentNode();
        if (oldparent != null) {
            oldparent.removeChild(newInternal);
        }

        // Convert to internal type, to avoid repeated casting
        ChildNode refInternal = (ChildNode)refChild;

        // Attach up
        newInternal.ownerNode = this;
        newInternal.isOwned(true);

        // Attach before and after
        // Note: firstChild.previousSibling == lastChild!!
        if (firstChild == null) {
            // this our first and only child
            firstChild = newInternal;
            newInternal.isFirstChild(true);
            newInternal.previousSibling = newInternal;
        }
        else {
            if (refInternal == null) {
                // this is an append
                ChildNode lastChild = firstChild.previousSibling;
                lastChild.nextSibling = newInternal;
                newInternal.previousSibling = lastChild;
                firstChild.previousSibling = newInternal;
            }
            else {
                // this is an insert
                if (refChild == firstChild) {
                    // at the head of the list
                    firstChild.isFirstChild(false);
                    newInternal.nextSibling = firstChild;
                    newInternal.previousSibling = firstChild.previousSibling;
                    firstChild.previousSibling = newInternal;
                    firstChild = newInternal;
                    newInternal.isFirstChild(true);
                }
                else {
                    // somewhere in the middle
                    ChildNode prev = refInternal.previousSibling;
                    newInternal.nextSibling = refInternal;
                    prev.nextSibling = newInternal;
                    refInternal.previousSibling = newInternal;
                    newInternal.previousSibling = prev;
                }
            }
        }

        changed();

        // update cached length if we have any
        if (fNodeListCache != null) {
            if (fNodeListCache.fLength != -1) {
                fNodeListCache.fLength++;
            }
            if (fNodeListCache.fChildIndex != -1) {
                // if we happen to insert just before the cached node, update
                // the cache to the new node to match the cached index
                if (fNodeListCache.fChild == refInternal) {
                    fNodeListCache.fChild = newInternal;
                } else {
                    // otherwise just invalidate the cache
                    fNodeListCache.fChildIndex = -1;
                }
            }
        }

        // notify document
        ownerDocument.insertedNode(this, newInternal, replace);

        checkNormalizationAfterInsert(newInternal);

        return newChild;

    
org.w3c.dom.NodeinternalRemoveChild(org.w3c.dom.Node oldChild, boolean replace)
NON-DOM INTERNAL: Within DOM actions,we sometimes need to be able to control which mutation events are spawned. This version of the removeChild operation allows us to do so. It is not intended for use by application programs.


        CoreDocumentImpl ownerDocument = ownerDocument();
        if (ownerDocument.errorChecking) {
            if (isReadOnly()) {
                throw new DOMException(
                            DOMException.NO_MODIFICATION_ALLOWED_ERR, 
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "NO_MODIFICATION_ALLOWED_ERR", null));
            }
            if (oldChild != null && oldChild.getParentNode() != this) {
                throw new DOMException(DOMException.NOT_FOUND_ERR, 
                            DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "NOT_FOUND_ERR", null));
            }
        }

        ChildNode oldInternal = (ChildNode) oldChild;

        // notify document
        ownerDocument.removingNode(this, oldInternal, replace);

        // update cached length if we have any
        if (fNodeListCache != null) {
            if (fNodeListCache.fLength != -1) {
                fNodeListCache.fLength--;
            }
            if (fNodeListCache.fChildIndex != -1) {
                // if the removed node is the cached node
                // move the cache to its (soon former) previous sibling
                if (fNodeListCache.fChild == oldInternal) {
                    fNodeListCache.fChildIndex--;
                    fNodeListCache.fChild = oldInternal.previousSibling();
                } else {
                    // otherwise just invalidate the cache
                    fNodeListCache.fChildIndex = -1;
                }
            }
        }

        // Patch linked list around oldChild
        // Note: lastChild == firstChild.previousSibling
        if (oldInternal == firstChild) {
            // removing first child
            oldInternal.isFirstChild(false);
            firstChild = oldInternal.nextSibling;
            if (firstChild != null) {
                firstChild.isFirstChild(true);
                firstChild.previousSibling = oldInternal.previousSibling;
            }
        } else {
            ChildNode prev = oldInternal.previousSibling;
            ChildNode next = oldInternal.nextSibling;
            prev.nextSibling = next;
            if (next == null) {
                // removing last child
                firstChild.previousSibling = prev;
            } else {
                // removing some other child in the middle
                next.previousSibling = prev;
            }
        }

        // Save previous sibling for normalization checking.
        ChildNode oldPreviousSibling = oldInternal.previousSibling();

        // Remove oldInternal's references to tree
        oldInternal.ownerNode       = ownerDocument;
        oldInternal.isOwned(false);
        oldInternal.nextSibling     = null;
        oldInternal.previousSibling = null;

        changed();

        // notify document
        ownerDocument.removedNode(this, replace);

        checkNormalizationAfterRemove(oldPreviousSibling);

        return oldInternal;

    
public booleanisEqualNode(org.w3c.dom.Node arg)
DOM Level 3 WD- Experimental. Override inherited behavior from NodeImpl to support deep equal.

        if (!super.isEqualNode(arg)) {
            return false;
        }
        // there are many ways to do this test, and there isn't any way
        // better than another. Performance may vary greatly depending on
        // the implementations involved. This one should work fine for us.
        Node child1 = getFirstChild();
        Node child2 = arg.getFirstChild();
        while (child1 != null && child2 != null) {
            if (!((NodeImpl) child1).isEqualNode(child2)) {
                return false;
            }
            child1 = child1.getNextSibling();
            child2 = child2.getNextSibling();
        }
        if (child1 != child2) {
            return false;
        }
        return true;
    
public org.w3c.dom.Nodeitem(int index)
NodeList method: Return the Nth immediate child of this node, or null if the index is out of bounds.

return
org.w3c.dom.Node
param
index int

        return nodeListItem(index);
    
final com.sun.org.apache.xerces.internal.dom.ChildNodelastChild()

        // last child is stored as the previous sibling of first child
        return firstChild != null ? firstChild.previousSibling : null;
    
final voidlastChild(com.sun.org.apache.xerces.internal.dom.ChildNode node)

        // store lastChild as previous sibling of first child
        if (firstChild != null) {
            firstChild.previousSibling = node;
        }
    
private intnodeListGetLength()
Count the immediate children of this node. Use to implement NodeList.getLength().

return
int


        if (fNodeListCache == null) {
            // get rid of trivial cases
            if (firstChild == null) {
                return 0;
            }
            if (firstChild == lastChild()) {
                return 1;
            }
            // otherwise request a cache object
            fNodeListCache = ownerDocument.getNodeListCache(this);
        }
        if (fNodeListCache.fLength == -1) { // is the cached length invalid ?
            int l;
            ChildNode n;
            // start from the cached node if we have one
            if (fNodeListCache.fChildIndex != -1 &&
                fNodeListCache.fChild != null) {
                l = fNodeListCache.fChildIndex;
                n = fNodeListCache.fChild;
            } else {
                n = firstChild;
                l = 0;
            }
            while (n != null) {
                l++;
                n = n.nextSibling;
            }
            fNodeListCache.fLength = l;
        }

        return fNodeListCache.fLength;

    
private org.w3c.dom.NodenodeListItem(int index)
Return the Nth immediate child of this node, or null if the index is out of bounds. Use to implement NodeList.item().

param
index int


        if (fNodeListCache == null) {
            // get rid of trivial case
            if (firstChild == lastChild()) {
                return index == 0 ? firstChild : null;
            }
            // otherwise request a cache object
            fNodeListCache = ownerDocument.getNodeListCache(this);
        }
        int i = fNodeListCache.fChildIndex;
        ChildNode n = fNodeListCache.fChild;
        boolean firstAccess = true;
        // short way
        if (i != -1 && n != null) {
            firstAccess = false;
            if (i < index) {
                while (i < index && n != null) {
                    i++;
                    n = n.nextSibling;
                }
            }
            else if (i > index) {
                while (i > index && n != null) {
                    i--;
                    n = n.previousSibling();
                }
            }
        }
        else {
            // long way
            n = firstChild;
            for (i = 0; i < index && n != null; i++) {
                n = n.nextSibling;
            }
        }

        // release cache if reaching last child or first child
        if (!firstAccess && (n == firstChild || n == lastChild())) {
            fNodeListCache.fChildIndex = -1;
            fNodeListCache.fChild = null;
            ownerDocument.freeNodeListCache(fNodeListCache);
            // we can keep using the cache until it is actually reused
            // fNodeListCache will be nulled by the pool (document) if that
            // happens.
            // fNodeListCache = null;
        }
        else {
            // otherwise update it
            fNodeListCache.fChildIndex = i;
            fNodeListCache.fChild = n;
        }
        return n;

    
public voidnormalize()
Override default behavior to call normalize() on this Node's children. It is up to implementors or Node to override normalize() to take action.

        // No need to normalize if already normalized.
        if (isNormalized()) {
            return;
        }
        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        ChildNode kid;
        for (kid = firstChild; kid != null; kid = kid.nextSibling) {
            kid.normalize();
        }
        isNormalized(true);
    
com.sun.org.apache.xerces.internal.dom.CoreDocumentImplownerDocument()
same as above but returns internal type and this one is not overridden by CoreDocumentImpl to return null

        return ownerDocument;
    
private voidreadObject(java.io.ObjectInputStream ois)
Deserialize object.


        // perform default deseralization
        ois.defaultReadObject();

        // hardset synchildren - so we don't try to sync - it does not make any
        // sense to try to synchildren when we just deserialize object.
        needsSyncChildren(false);

    
public org.w3c.dom.NoderemoveChild(org.w3c.dom.Node oldChild)
Remove a child from this Node. The removed child's subtree remains intact so it may be re-inserted elsewhere.

return
oldChild, in its new state (removed).
throws
DOMException(NOT_FOUND_ERR) if oldChild is not a child of this node.
throws
DOMException(NO_MODIFICATION_ALLOWED_ERR) if this node is read-only.

        // Tail-call, should be optimizable
        return internalRemoveChild(oldChild, false);
    
public org.w3c.dom.NodereplaceChild(org.w3c.dom.Node newChild, org.w3c.dom.Node oldChild)
Make newChild occupy the location that oldChild used to have. Note that newChild will first be removed from its previous parent, if any. Equivalent to inserting newChild before oldChild, then removing oldChild.

return
oldChild, in its new state (removed).
throws
DOMException(HIERARCHY_REQUEST_ERR) if newChild is of a type that shouldn't be a child of this node, or if newChild is one of our ancestors.
throws
DOMException(WRONG_DOCUMENT_ERR) if newChild has a different owner document than we do.
throws
DOMException(NOT_FOUND_ERR) if oldChild is not a child of this node.
throws
DOMException(NO_MODIFICATION_ALLOWED_ERR) if this node is read-only.

        // If Mutation Events are being generated, this operation might
        // throw aggregate events twice when modifying an Attr -- once 
        // on insertion and once on removal. DOM Level 2 does not specify 
        // this as either desirable or undesirable, but hints that
        // aggregations should be issued only once per user request.

        // notify document
        ownerDocument.replacingNode(this);

        internalInsertBefore(newChild, oldChild, true);
        if (newChild != oldChild) {
            internalRemoveChild(oldChild, true);
        }

        // notify document
        ownerDocument.replacedNode(this);

        return oldChild;
    
voidsetOwnerDocument(com.sun.org.apache.xerces.internal.dom.CoreDocumentImpl doc)
NON-DOM set the ownerDocument of this node and its children

        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        super.setOwnerDocument(doc);
        ownerDocument = doc;
	for (ChildNode child = firstChild;
	     child != null; child = child.nextSibling) {
	    child.setOwnerDocument(doc);
	}
    
public voidsetReadOnly(boolean readOnly, boolean deep)
Override default behavior so that if deep is true, children are also toggled.

see
Node

Note: this will not change the state of an EntityReference or its children, which are always read-only.


        super.setReadOnly(readOnly, deep);

        if (deep) {

            if (needsSyncChildren()) {
                synchronizeChildren();
            }

            // Recursively set kids
            for (ChildNode mykid = firstChild;
                 mykid != null;
                 mykid = mykid.nextSibling) {
                if (mykid.getNodeType() != Node.ENTITY_REFERENCE_NODE) {
                    mykid.setReadOnly(readOnly,true);
                }
            }
        }
    
public voidsetTextContent(java.lang.String textContent)

        // get rid of any existing children
        Node child;
        while ((child = getFirstChild()) != null) {
            removeChild(child);
        }
        // create a Text node to hold the given content
        if (textContent != null && textContent.length() != 0){
            appendChild(ownerDocument().createTextNode(textContent));
        }
    
protected voidsynchronizeChildren()
Override this method in subclass to hook in efficient internal data structure.

        // By default just change the flag to avoid calling this method again
        needsSyncChildren(false);
    
private voidwriteObject(java.io.ObjectOutputStream out)
Serialize object.


        // synchronize chilren
        if (needsSyncChildren()) {
            synchronizeChildren();
        }
        // write object
        out.defaultWriteObject();