package org.pdf4j.saxon.tree;
import org.pdf4j.saxon.Configuration;
import org.pdf4j.saxon.event.Builder;
import org.pdf4j.saxon.om.*;
import org.pdf4j.saxon.pattern.AnyNodeTest;
import org.pdf4j.saxon.pattern.NameTest;
import org.pdf4j.saxon.pattern.NodeTest;
import org.pdf4j.saxon.trans.Err;
import org.pdf4j.saxon.trans.XPathException;
import org.pdf4j.saxon.type.SchemaType;
import org.pdf4j.saxon.type.Type;
import org.pdf4j.saxon.value.UntypedAtomicValue;
import org.pdf4j.saxon.value.Value;
import javax.xml.transform.SourceLocator;
/**
* A node in the "linked" tree representing any kind of node except a namespace node.
* Specific node kinds are represented by concrete subclasses.
*
* @author Michael H. Kay
*/
public abstract class NodeImpl
implements MutableNodeInfo, FingerprintedNode, SiblingCountingNode, SourceLocator {
protected ParentNodeImpl parent;
protected int index;
/**
* Chararacteristic letters to identify each type of node, indexed using the node type
* values. These are used as the initial letter of the result of generate-id()
*/
public static final char[] NODE_LETTER =
{'x', 'e', 'a', 't', 'x', 'x', 'x', 'p', 'c', 'r', 'x', 'x', 'x', 'n'};
/**
* Get the value of the item as a CharSequence. This is in some cases more efficient than
* the version of the method that returns a String.
*/
public CharSequence getStringValueCS() {
return getStringValue();
}
/**
* Get the type annotation of this node, if any
* @return the type annotation, as the integer name code of the type name
*/
public int getTypeAnnotation() {
return StandardNames.XS_UNTYPED;
}
/**
* Get the column number of the node.
* The default implementation returns -1, meaning unknown
*/
public int getColumnNumber() {
if (parent == null) {
return -1;
} else {
return parent.getColumnNumber();
}
}
/**
* Get the public identifier of the document entity containing this node.
* The default implementation returns null, meaning unknown
*/
public String getPublicId() {
return null;
}
/**
* Get the document number of the document containing this node. For a free-standing
* orphan node, just return the hashcode.
*/
public int getDocumentNumber() {
return getPhysicalRoot().getDocumentNumber();
}
/**
* Get the index position of this node among its siblings (starting from 0)
* @return 0 for the first child, 1 for the second child, etc.
*/
public int getSiblingPosition() {
return index;
}
/**
* Get the typed value of this node.
* If there is no type annotation, we return the string value, as an instance
* of xs:untypedAtomic
*/
public SequenceIterator getTypedValue() throws XPathException {
int annotation = getTypeAnnotation();
if ((annotation & NodeInfo.IS_DTD_TYPE) != 0) {
annotation = StandardNames.XS_UNTYPED_ATOMIC;
}
annotation &= NamePool.FP_MASK;
if (annotation == -1 || annotation == StandardNames.XS_UNTYPED_ATOMIC || annotation == StandardNames.XS_UNTYPED) {
return SingletonIterator.makeIterator(new UntypedAtomicValue(getStringValueCS()));
} else {
SchemaType stype = getConfiguration().getSchemaType(annotation);
if (stype == null) {
String typeName;
try {
typeName = getNamePool().getDisplayName(annotation);
} catch (Exception err) {
typeName = annotation + "";
}
throw new XPathException("Unknown type annotation " +
Err.wrap(typeName) + " in document instance");
} else {
return stype.getTypedValue(this);
}
}
}
/**
* Get the typed value. The result of this method will always be consistent with the method
* {@link org.pdf4j.saxon.om.Item#getTypedValue()}. However, this method is often more convenient and may be
* more efficient, especially in the common case where the value is expected to be a singleton.
*
* @return the typed value. If requireSingleton is set to true, the result will always be an
* AtomicValue. In other cases it may be a Value representing a sequence whose items are atomic
* values.
* @since 8.5
*/
public Value atomize() throws XPathException {
int annotation = getTypeAnnotation();
if ((annotation & NodeInfo.IS_DTD_TYPE) != 0) {
annotation = StandardNames.XS_UNTYPED_ATOMIC;
}
if (annotation == -1 || annotation == StandardNames.XS_UNTYPED_ATOMIC || annotation == StandardNames.XS_UNTYPED) {
return new UntypedAtomicValue(getStringValueCS());
} else {
SchemaType stype = getConfiguration().getSchemaType(annotation);
if (stype == null) {
String typeName = getNamePool().getDisplayName(annotation);
throw new XPathException("Unknown type annotation " +
Err.wrap(typeName) + " in document instance");
} else {
return stype.atomize(this);
}
}
}
/**
* Set the system ID of this node. This method is provided so that a NodeInfo
* implements the javax.xml.transform.Source interface, allowing a node to be
* used directly as the Source of a transformation
*/
public void setSystemId(String uri) {
// overridden in DocumentImpl and ElementImpl
getParent().setSystemId(uri);
}
/**
* Determine whether this is the same node as another node
*
* @return true if this Node object and the supplied Node object represent the
* same node in the tree.
*/
public boolean isSameNodeInfo(NodeInfo other) {
// default implementation: differs for attribute and namespace nodes
return this == other;
}
/**
* The equals() method compares nodes for identity. It is defined to give the same result
* as isSameNodeInfo().
* @param other the node to be compared with this node
* @return true if this NodeInfo object and the supplied NodeInfo object represent
* the same node in the tree.
* @since 8.7 Previously, the effect of the equals() method was not defined. Callers
* should therefore be aware that third party implementations of the NodeInfo interface may
* not implement the correct semantics. It is safer to use isSameNodeInfo() for this reason.
* The equals() method has been defined because it is useful in contexts such as a Java Set or HashMap.
*/
public boolean equals(Object other) {
return other instanceof NodeInfo && isSameNodeInfo((NodeInfo)other);
}
/**
* The hashCode() method obeys the contract for hashCode(): that is, if two objects are equal
* (represent the same node) then they must have the same hashCode()
* @since 8.7 Previously, the effect of the equals() and hashCode() methods was not defined. Callers
* should therefore be aware that third party implementations of the NodeInfo interface may
* not implement the correct semantics.
*/
// public int hashCode() {
// FastStringBuffer buff = new FastStringBuffer(20);
// generateId(buff);
// return buff.toString().hashCode();
// }
/**
* Get the nameCode of the node. This is used to locate the name in the NamePool
*/
public int getNameCode() {
// default implementation: return -1 for an unnamed node
return -1;
}
/**
* Get the fingerprint of the node. This is used to compare whether two nodes
* have equivalent names. Return -1 for a node with no name.
*/
public int getFingerprint() {
int nameCode = getNameCode();
if (nameCode == -1) {
return -1;
}
return nameCode & 0xfffff;
}
/**
* Get a character string that uniquely identifies this node within this document
* (The calling code will prepend a document identifier)
*/
public void generateId(FastStringBuffer buffer) {
long seq = getSequenceNumber();
if (seq == -1L) {
getPhysicalRoot().generateId(buffer);
buffer.append(NODE_LETTER[getNodeKind()]);
buffer.append(Long.toString(seq));
} else {
parent.generateId(buffer);
buffer.append(NODE_LETTER[getNodeKind()]);
buffer.append(Integer.toString(index));
}
}
/**
* Get the system ID for the node. Default implementation for child nodes.
*/
public String getSystemId() {
return parent.getSystemId();
}
/**
* Get the base URI for the node. Default implementation for child nodes.
*/
public String getBaseURI() {
return parent.getBaseURI();
}
/**
* Get the node sequence number (in document order). Sequence numbers are monotonic but not
* consecutive. In the current implementation, parent nodes (elements and roots) have a zero
* least-significant word, while namespaces, attributes, text nodes, comments, and PIs have
* the top word the same as their owner and the bottom half reflecting their relative position.
* This is the default implementation for child nodes.
* For nodes added by XQUery Update, the sequence number is -1L
* @return the sequence number if there is one, or -1L otherwise.
*/
protected long getSequenceNumber() {
NodeImpl prev = this;
for (int i = 0; ; i++) {
if (prev instanceof ParentNodeImpl) {
long prevseq = prev.getSequenceNumber();
return (prevseq == -1L ? prevseq : prevseq + 0x10000 + i);
// note the 0x10000 is to leave room for namespace and attribute nodes.
}
prev = prev.getPreviousInDocument();
}
}
/**
* Determine the relative position of this node and another node, in document order.
* The other node will always be in the same document.
*
* @param other The other node, whose position is to be compared with this node
* @return -1 if this node precedes the other node, +1 if it follows the other
* node, or 0 if they are the same node. (In this case, isSameNode() will always
* return true, and the two nodes will produce the same result for generateId())
*/
public final int compareOrder(NodeInfo other) {
if (other instanceof NamespaceIterator.NamespaceNodeImpl) {
return 0 - other.compareOrder(this);
}
long a = getSequenceNumber();
long b = ((NodeImpl)other).getSequenceNumber();
if (a == -1L || b == -1L) {
// Nodes added by XQuery Update do not have sequence numbers
return Navigator.compareOrder(this, ((NodeImpl)other));
}
if (a < b) {
return -1;
}
if (a > b) {
return +1;
}
return 0;
}
/**
* Get the configuration
*/
public Configuration getConfiguration() {
return getPhysicalRoot().getConfiguration();
}
/**
* Get the NamePool
*/
public NamePool getNamePool() {
return getPhysicalRoot().getNamePool();
}
/**
* Get the prefix part of the name of this node. This is the name before the ":" if any.
*
* @return the prefix part of the name. For an unnamed node, return an empty string.
*/
public String getPrefix() {
int nameCode = getNameCode();
if (nameCode == -1) {
return "";
}
if (NamePool.getPrefixIndex(nameCode) == 0) {
return "";
}
return getNamePool().getPrefix(nameCode);
}
/**
* Get the URI part of the name of this node. This is the URI corresponding to the
* prefix, or the URI of the default namespace if appropriate.
*
* @return The URI of the namespace of this node. For the null namespace, return an
* empty string. For an unnamed node, return the empty string.
*/
public String getURI() {
int nameCode = getNameCode();
if (nameCode == -1) {
return "";
}
return getNamePool().getURI(nameCode);
}
/**
* Get the display name of this node. For elements and attributes this is [prefix:]localname.
* For unnamed nodes, it is an empty string.
*
* @return The display name of this node.
* For a node with no name, return an empty string.
*/
public String getDisplayName() {
int nameCode = getNameCode();
if (nameCode == -1) {
return "";
}
return getNamePool().getDisplayName(nameCode);
}
/**
* Get the local name of this node.
*
* @return The local name of this node.
* For a node with no name, return "",.
*/
public String getLocalPart() {
int nameCode = getNameCode();
if (nameCode == -1) {
return "";
}
return getNamePool().getLocalName(nameCode);
}
/**
* Get the line number of the node within its source document entity
*/
public int getLineNumber() {
return parent.getLineNumber();
}
/**
* Find the parent node of this node.
*
* @return The Node object describing the containing element or root node.
*/
public final NodeInfo getParent() {
if (parent instanceof DocumentImpl && ((DocumentImpl)parent).isImaginary()) {
return null;
}
return parent;
}
/**
* Get the previous sibling of the node
*
* @return The previous sibling node. Returns null if the current node is the first
* child of its parent.
*/
public NodeInfo getPreviousSibling() {
if (parent == null) {
return null;
}
return parent.getNthChild(index - 1);
}
/**
* Get next sibling node
*
* @return The next sibling node of the required type. Returns null if the current node is the last
* child of its parent.
*/
public NodeInfo getNextSibling() {
if (parent == null) {
return null;
}
return parent.getNthChild(index + 1);
}
/**
* Get first child - default implementation used for leaf nodes
*
* @return null
*/
public NodeInfo getFirstChild() {
return null;
}
/**
* Get last child - default implementation used for leaf nodes
*
* @return null
*/
public NodeInfo getLastChild() {
return null;
}
/**
* Return an enumeration over the nodes reached by the given axis from this node
*
* @param axisNumber The axis to be iterated over
* @return an AxisIterator that scans the nodes reached by the axis in turn.
*/
public AxisIterator iterateAxis(byte axisNumber) {
// Fast path for child axis
if (axisNumber == Axis.CHILD) {
if (this instanceof ParentNodeImpl) {
return ((ParentNodeImpl)this).enumerateChildren(null);
} else {
return EmptyIterator.getInstance();
}
} else {
return iterateAxis(axisNumber, AnyNodeTest.getInstance());
}
}
/**
* Return an enumeration over the nodes reached by the given axis from this node
*
* @param axisNumber The axis to be iterated over
* @param nodeTest A pattern to be matched by the returned nodes
* @return an AxisIterator that scans the nodes reached by the axis in turn.
*/
public AxisIterator iterateAxis(byte axisNumber, NodeTest nodeTest) {
switch (axisNumber) {
case Axis.ANCESTOR:
return new AncestorEnumeration(this, nodeTest, false);
case Axis.ANCESTOR_OR_SELF:
return new AncestorEnumeration(this, nodeTest, true);
case Axis.ATTRIBUTE:
if (getNodeKind() != Type.ELEMENT) {
return EmptyIterator.getInstance();
}
return new AttributeEnumeration(this, nodeTest);
case Axis.CHILD:
if (this instanceof ParentNodeImpl) {
return ((ParentNodeImpl)this).enumerateChildren(nodeTest);
} else {
return EmptyIterator.getInstance();
}
case Axis.DESCENDANT:
if (getNodeKind() == Type.DOCUMENT &&
nodeTest instanceof NameTest &&
nodeTest.getPrimitiveType() == Type.ELEMENT) {
return ((DocumentImpl)this).getAllElements(nodeTest.getFingerprint());
} else if (hasChildNodes()) {
return new DescendantEnumeration(this, nodeTest, false);
} else {
return EmptyIterator.getInstance();
}
case Axis.DESCENDANT_OR_SELF:
return new DescendantEnumeration(this, nodeTest, true);
case Axis.FOLLOWING:
return new FollowingEnumeration(this, nodeTest);
case Axis.FOLLOWING_SIBLING:
return new FollowingSiblingEnumeration(this, nodeTest);
case Axis.NAMESPACE:
if (getNodeKind() != Type.ELEMENT) {
return EmptyIterator.getInstance();
}
return NamespaceIterator.makeIterator(this, nodeTest);
case Axis.PARENT:
NodeInfo parent = getParent();
if (parent == null) {
return EmptyIterator.getInstance();
}
return Navigator.filteredSingleton(parent, nodeTest);
case Axis.PRECEDING:
return new PrecedingEnumeration(this, nodeTest);
case Axis.PRECEDING_SIBLING:
return new PrecedingSiblingEnumeration(this, nodeTest);
case Axis.SELF:
return Navigator.filteredSingleton(this, nodeTest);
case Axis.PRECEDING_OR_ANCESTOR:
return new PrecedingOrAncestorEnumeration(this, nodeTest);
default:
throw new IllegalArgumentException("Unknown axis number " + axisNumber);
}
}
/**
* Find the value of a given attribute of this node. <BR>
* This method is defined on all nodes to meet XSL requirements, but for nodes
* other than elements it will always return null.
* @param uri the namespace uri of an attribute
* @param localName the local name of an attribute
* @return the value of the attribute, if it exists, otherwise null
*/
// public String getAttributeValue( String uri, String localName ) {
// return null;
// }
/**
* Find the value of a given attribute of this node. <BR>
* This method is defined on all nodes to meet XSL requirements, but for nodes
* other than elements it will always return null.
* @param name the name of an attribute. This must be an unqualified attribute name,
* i.e. one with no namespace prefix.
* @return the value of the attribute, if it exists, otherwise null
*/
//public String getAttributeValue( String name ) {
// return null;
//}
/**
* Get the value of a given attribute of this node
*
* @param fingerprint The fingerprint of the attribute name
* @return the attribute value if it exists or null if not
*/
public String getAttributeValue(int fingerprint) {
return null;
}
/**
* Get the root node
* @return the NodeInfo representing the logical root of the tree. For this tree implementation the
* root will either be a document node or an element node.
*/
public NodeInfo getRoot() {
NodeInfo parent = getParent();
if (parent == null) {
return this;
} else {
return parent.getRoot();
}
}
/**
* Get the root (document) node
* @return the DocumentInfo representing the containing document. If this
* node is part of a tree that does not have a document node as its
* root, returns null.
*/
public DocumentInfo getDocumentRoot() {
NodeInfo parent = getParent();
if (parent == null) {
return null;
} else {
return parent.getDocumentRoot();
}
}
/**
* Get the physical root of the tree. This may be an imaginary document node: this method
* should be used only when control information held at the physical root is required
* @return the document node, which may be imaginary. In the case of a node that has been detached
* from the tree by means of a delete() operation, this method returns null.
*/
public DocumentImpl getPhysicalRoot() {
ParentNodeImpl up = parent;
while (up != null && !(up instanceof DocumentImpl)) {
up = up.parent;
}
return (DocumentImpl)up;
}
/**
* Get the next node in document order
*
* @param anchor the scan stops when it reaches a node that is not a descendant of the specified
* anchor node
* @return the next node in the document, or null if there is no such node
*/
public NodeImpl getNextInDocument(NodeImpl anchor) {
// find the first child node if there is one; otherwise the next sibling node
// if there is one; otherwise the next sibling of the parent, grandparent, etc, up to the anchor element.
// If this yields no result, return null.
NodeImpl next = (NodeImpl)getFirstChild();
if (next != null) {
return next;
}
if (this == anchor) {
return null;
}
next = (NodeImpl)getNextSibling();
if (next != null) {
return next;
}
NodeImpl parent = this;
while (true) {
parent = (NodeImpl)parent.getParent();
if (parent == null) {
return null;
}
if (parent == anchor) {
return null;
}
next = (NodeImpl)parent.getNextSibling();
if (next != null) {
return next;
}
}
}
/**
* Get the previous node in document order
*
* @return the previous node in the document, or null if there is no such node
*/
public NodeImpl getPreviousInDocument() {
// finds the last child of the previous sibling if there is one;
// otherwise the previous sibling element if there is one;
// otherwise the parent, up to the anchor element.
// If this reaches the document root, return null.
NodeImpl prev = (NodeImpl)getPreviousSibling();
if (prev != null) {
return prev.getLastDescendantOrSelf();
}
return (NodeImpl)getParent();
}
private NodeImpl getLastDescendantOrSelf() {
NodeImpl last = (NodeImpl)getLastChild();
if (last == null) {
return this;
}
return last.getLastDescendantOrSelf();
}
/**
* Get all namespace undeclarations and undeclarations defined on this element.
*
* @param buffer If this is non-null, and the result array fits in this buffer, then the result
* may overwrite the contents of this array, to avoid the cost of allocating a new array on the heap.
* @return An array of integers representing the namespace declarations and undeclarations present on
* this element. For a node other than an element, return null. Otherwise, the returned array is a
* sequence of namespace codes, whose meaning may be interpreted by reference to the name pool. The
* top half word of each namespace code represents the prefix, the bottom half represents the URI.
* If the bottom half is zero, then this is a namespace undeclaration rather than a declaration.
* The XML namespace is never included in the list. If the supplied array is larger than required,
* then the first unused entry will be set to -1.
* <p/>
* <p>For a node other than an element, the method returns null.</p>
*/
public int[] getDeclaredNamespaces(int[] buffer) {
return null;
}
/**
* Copy nodes. Copying type annotations is not yet supported for this tree
* structure, so we simply map the new interface onto the old
*/
// public final void copy(Receiver out, int whichNamespaces, boolean copyAnnotations, int locationId)
// throws XPathException {
// copy(out, whichNamespaces);
// }
//
// public abstract void copy(Receiver out, int whichNamespaces) throws XPathException;
// implement DOM Node methods
/**
* Determine whether the node has any children.
*
* @return <code>true</code> if the node has any children,
* <code>false</code> if the node has no children.
*/
public boolean hasChildNodes() {
return getFirstChild() != null;
}
/**
* Determine whether this node has the is-id property
*
* @return true if the node is an ID
*/
public boolean isId() {
return false;
}
/**
* Determine whether this node has the is-idref property
*
* @return true if the node is an IDREF or IDREFS element or attribute
*/
public boolean isIdref() {
return false;
}
/**
* Determine whether the node has the is-nilled property
*
* @return true if the node has the is-nilled property
*/
public boolean isNilled() {
return false;
}
/**
* Set the type annotation on a node. This must only be called when the caller has verified (by validation)
* that the node is a valid instance of the specified type. The call is ignored if the node is not an element
* or attribute node.
*
* @param typeCode the type annotation (possibly including high bits set to indicate the isID, isIDREF, and
* isNilled properties)
*/
public void setTypeAnnotation(int typeCode) {
// no action
}
/**
* Delete this node (that is, detach it from its parent)
*/
public void delete() {
// Overridden for attribute nodes
if (parent != null) {
parent.removeChild(this);
DocumentImpl newRoot = new DocumentImpl();
newRoot.setConfiguration(parent.getConfiguration());
newRoot.setImaginary(true);
parent = newRoot;
}
index = -1;
}
/**
* Remove an attribute from this element node
*
* <p>If this node is not an element, or if it has no attribute with the specified name,
* this method takes no action.</p>
*
* <p>The attribute node itself is not modified in any way.</p>
* @param nameCode the name of the attribute to be removed
*/
public void removeAttribute(int nameCode) {
// no action (overridden in subclasses)
}
/**
* Add an attribute to this element node.
* <p/>
* <p>If this node is not an element, or if the supplied node is not an attribute, the method
* takes no action. If the element already has an attribute with this name, the existing attribute
* is replaced.</p>
*
* @param nameCode the name of the new attribute
* @param typeCode the type annotation of the new attribute
* @param value the string value of the new attribute
* @param properties properties including IS_ID and IS_IDREF properties
*/
public void putAttribute(int nameCode, int typeCode, CharSequence value, int properties) {
// No action, unless this is an element node
}
/**
* Rename this node
* @param newNameCode the NamePool code of the new name
*/
public void rename(int newNameCode) {
// implemented for node kinds that have a name
}
public void addNamespace(int nscode, boolean inherit) {
// implemented for element nodes only
}
/**
* Replace this node with a given sequence of nodes *
* @param replacement the replacement nodes
* @param inherit set to true if new child elements are to inherit the in-scope namespaces
* of their new parent
* @throws IllegalArgumentException if any of the replacement nodes is not an element, text,
* comment, or processing instruction node
*/
public void replace(NodeInfo[] replacement, boolean inherit) {
parent.replaceChildrenAt(replacement, index, inherit);
}
/**
* Insert copies of a sequence of nodes as children of this node.
* <p/>
* <p>This method takes no action unless the target node is a document node or element node. It also
* takes no action in respect of any supplied nodes that are not elements, text nodes, comments, or
* processing instructions.</p>
* <p/>
* <p>The supplied nodes will be copied to form the new children. Adjacent text nodes will be merged, and
* zero-length text nodes removed.</p>
*
* @param source the nodes to be inserted
* @param atStart true if the new nodes are to be inserted before existing children; false if they are
* @param inherit true if the inserted nodes are to inherit the namespaces that are in-scope for their
* new parent; false if such namespaces should be undeclared on the children
*/
public void insertChildren(NodeInfo[] source, boolean atStart, boolean inherit) {
throw new UnsupportedOperationException("insertChildren() can only be applied to a parent node");
}
/**
* Insert copies of a sequence of nodes as siblings of this node.
* <p/>
* <p>This method takes no action unless the target node is an element, text node, comment, or
* processing instruction, and one that has a parent node. It also
* takes no action in respect of any supplied nodes that are not elements, text nodes, comments, or
* processing instructions.</p>
* <p/>
* <p>The supplied nodes must use the same data model implementation as the tree into which they
* will be inserted.</p>
*
* @param source the nodes to be inserted
* @param before true if the new nodes are to be inserted before the target node; false if they are
* @param inherit
*/
public void insertSiblings(NodeInfo[] source, boolean before, boolean inherit) {
if (parent == null) {
throw new IllegalStateException("Cannot add siblings if there is no parent");
}
parent.insertChildrenAt(source, (before ? index : index+1), inherit);
}
/**
* Remove type information from this node (and its ancestors, recursively).
* This method implements the upd:removeType() primitive defined in the XQuery Update specification
*/
public void removeTypeAnnotation() {
// no action
}
/**
* Get a Builder suitable for building nodes that can be attached to this document.
* @return a new Builder that constructs nodes using the same object model implementation
* as this one, suitable for attachment to this tree
*/
public Builder newBuilder() {
return getPhysicalRoot().newBuilder();
}
}
//
// The contents of this file are subject to the Mozilla Public License Version 1.0 (the "License");
// you may not use this file except in compliance with the License. You may obtain a copy of the
// License at http://www.mozilla.org/MPL/
//
// Software distributed under the License is distributed on an "AS IS" basis,
// WITHOUT WARRANTY OF ANY KIND, either express or implied.
// See the License for the specific language governing rights and limitations under the License.
//
// The Original Code is: all this file.
//
// The Initial Developer of the Original Code is Michael H. Kay.
//
// Portions created by (your name) are Copyright (C) (your legal entity). All Rights Reserved.
//
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