DeferredDocumentImplpublic class DeferredDocumentImpl extends DocumentImpl implements DeferredNodeThe Document interface represents the entire HTML or XML document.
Conceptually, it is the root of the document tree, and provides the
primary access to the document's data.
Since elements, text nodes, comments, processing instructions,
etc. cannot exist outside the context of a Document, the Document
interface also contains the factory methods needed to create these
objects. The Node objects created have a ownerDocument attribute
which associates them with the Document within whose context they
were created.
<<<<<<< DeferredDocumentImpl.java |
Fields Summary |
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static final long | serialVersionUIDSerialization version. | private static final boolean | DEBUG_PRINT_REF_COUNTSTo include code for printing the ref count tables. | private static final boolean | DEBUG_PRINT_TABLESTo include code for printing the internal tables. | private static final boolean | DEBUG_IDSTo debug identifiers set to true and recompile. | protected static final int | CHUNK_SHIFTChunk shift. | protected static final int | CHUNK_SIZEChunk size. | protected static final int | CHUNK_MASKChunk mask. | protected static final int | INITIAL_CHUNK_COUNTInitial chunk size. | protected transient int | fNodeCountNode count. | protected transient int[] | fNodeTypeNode types. | protected transient Object[] | fNodeNameNode names. | protected transient Object[] | fNodeValueNode values. | protected transient int[] | fNodeParentNode parents. | protected transient int[] | fNodeLastChildNode first children. | protected transient int[] | fNodePrevSibNode prev siblings. | protected transient Object[] | fNodeURINode namespace URI. | protected transient int[] | fNodeExtraExtra data. | protected transient int | fIdCountIdentifier count. | protected transient String[] | fIdNameIdentifier name indexes. | protected transient int[] | fIdElementIdentifier element indexes. | protected boolean | fNamespacesEnabledDOM2: For namespace support in the deferred case. | private final transient StringBuffer | fBufferStr | private final transient Vector | fStrChunks | private static final int[] | INIT_ARRAY |
Constructors Summary |
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public DeferredDocumentImpl()NON-DOM: Actually creating a Document is outside the DOM's spec,
since it has to operate in terms of a particular implementation.
//
// Constructors
//
this(false);
| public DeferredDocumentImpl(boolean namespacesEnabled)NON-DOM: Actually creating a Document is outside the DOM's spec,
since it has to operate in terms of a particular implementation.
this(namespacesEnabled, false);
| public DeferredDocumentImpl(boolean namespaces, boolean grammarAccess)Experimental constructor.
super(grammarAccess);
needsSyncData(true);
needsSyncChildren(true);
fNamespacesEnabled = namespaces;
|
Methods Summary |
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public void | appendChild(int parentIndex, int childIndex)Appends a child to the specified parent in the table.
// append parent index
int pchunk = parentIndex >> CHUNK_SHIFT;
int pindex = parentIndex & CHUNK_MASK;
int cchunk = childIndex >> CHUNK_SHIFT;
int cindex = childIndex & CHUNK_MASK;
setChunkIndex(fNodeParent, parentIndex, cchunk, cindex);
// set previous sibling of new child
int olast = getChunkIndex(fNodeLastChild, pchunk, pindex);
setChunkIndex(fNodePrevSib, olast, cchunk, cindex);
// update parent's last child
setChunkIndex(fNodeLastChild, childIndex, pchunk, pindex);
| protected static int | binarySearch(int[] values, int start, int end, int target)Performs a binary search for a target value in an array of
values. The array of values must be in ascending sorted order
before calling this method and all array values must be
non-negative.
if (DEBUG_IDS) {
System.out.println("binarySearch(), target: "+target);
}
// look for target value
while (start <= end) {
// is this the one we're looking for?
int middle = (start + end) / 2;
int value = values[middle];
if (DEBUG_IDS) {
System.out.print(" value: "+value+", target: "+target+" // ");
print(values, start, end, middle, target);
}
if (value == target) {
while (middle > 0 && values[middle - 1] == target) {
middle--;
}
if (DEBUG_IDS) {
System.out.println("FOUND AT "+middle);
}
return middle;
}
// is this point higher or lower?
if (value > target) {
end = middle - 1;
}
else {
start = middle + 1;
}
} // while
// not found
if (DEBUG_IDS) {
System.out.println("NOT FOUND!");
}
return -1;
| private final int | clearChunkIndex(int[][] data, int chunk, int index)Clears the specified value in the given data at the chunk and index.
Note that this method will clear the given chunk if the reference
count becomes zero.
int value = data[chunk] != null ? data[chunk][index] : -1;
if (value != -1) {
data[chunk][CHUNK_SIZE]--;
data[chunk][index] = -1;
if (data[chunk][CHUNK_SIZE] == 0) {
data[chunk] = null;
}
}
return value;
| private final java.lang.String | clearChunkValue(java.lang.Object[][] data, int chunk, int index)
String value = data[chunk] != null ? (String)data[chunk][index] : null;
if (value != null) {
data[chunk][index] = null;
RefCount c = (RefCount) data[chunk][CHUNK_SIZE];
c.fCount--;
if (c.fCount == 0) {
data[chunk] = null;
}
}
return value;
| public int | cloneNode(int nodeIndex, boolean deep)Creates a clone of the specified node.
// clone immediate node
int nchunk = nodeIndex >> CHUNK_SHIFT;
int nindex = nodeIndex & CHUNK_MASK;
int nodeType = fNodeType[nchunk][nindex];
int cloneIndex = createNode((short)nodeType);
int cchunk = cloneIndex >> CHUNK_SHIFT;
int cindex = cloneIndex & CHUNK_MASK;
setChunkValue(fNodeName, fNodeName[nchunk][nindex], cchunk, cindex);
setChunkValue(fNodeValue, fNodeValue[nchunk][nindex], cchunk, cindex);
setChunkValue(fNodeURI, fNodeURI[nchunk][nindex], cchunk, cindex);
int extraIndex = fNodeExtra[nchunk][nindex];
if (extraIndex != -1) {
if (nodeType != Node.ATTRIBUTE_NODE && nodeType != Node.TEXT_NODE) {
extraIndex = cloneNode(extraIndex, false);
}
setChunkIndex(fNodeExtra, extraIndex, cchunk, cindex);
}
// clone and attach children
if (deep) {
int prevIndex = -1;
int childIndex = getLastChild(nodeIndex, false);
while (childIndex != -1) {
int clonedChildIndex = cloneNode(childIndex, deep);
insertBefore(cloneIndex, clonedChildIndex, prevIndex);
prevIndex = clonedChildIndex;
childIndex = getRealPrevSibling(childIndex, false);
}
}
// return cloned node index
return cloneIndex;
| private final void | createChunk(int[][] data, int chunk)Creates the specified chunk in the given array of chunks.
for (int i = 0; i < CHUNK_SIZE; i++) {
INIT_ARRAY[i] = -1;
}
data[chunk] = new int[CHUNK_SIZE + 1];
System.arraycopy(INIT_ARRAY, 0, data[chunk], 0, CHUNK_SIZE);
| private final void | createChunk(java.lang.Object[][] data, int chunk)
data[chunk] = new Object[CHUNK_SIZE + 1];
data[chunk][CHUNK_SIZE] = new RefCount();
| public int | createDeferredAttribute(java.lang.String attrName, java.lang.String attrValue, boolean specified)Creates an attribute in the table.
return createDeferredAttribute(attrName, null, attrValue, specified);
| public int | createDeferredAttribute(java.lang.String attrName, java.lang.String attrURI, java.lang.String attrValue, boolean specified)Creates an attribute with a URI in the table.
// create node
int nodeIndex = createNode(NodeImpl.ATTRIBUTE_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, attrName, chunk, index);
setChunkValue(fNodeURI, attrURI, chunk, index);
setChunkValue(fNodeValue, attrValue, chunk, index);
int extra = specified ? SPECIFIED : 0;
setChunkIndex(fNodeExtra, extra, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredCDATASection(java.lang.String data)Creates a CDATA section node in the table.
// create node
int nodeIndex = createNode(Node.CDATA_SECTION_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeValue, data, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredComment(java.lang.String data)Creates a comment node in the table.
// create node
int nodeIndex = createNode(Node.COMMENT_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeValue, data, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredDocument()Creates a document node in the table.
int nodeIndex = createNode(Node.DOCUMENT_NODE);
return nodeIndex;
| public int | createDeferredDocumentType(java.lang.String rootElementName, java.lang.String publicId, java.lang.String systemId)Creates a doctype.
// create node
int nodeIndex = createNode(Node.DOCUMENT_TYPE_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
// save name, public id, system id
setChunkValue(fNodeName, rootElementName, chunk, index);
setChunkValue(fNodeValue, publicId, chunk, index);
setChunkValue(fNodeURI, systemId, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredElement(java.lang.String elementURI, java.lang.String elementName, org.w3c.dom.TypeInfo type)Creates an element node with a URI in the table and type information.
// create node
int elementNodeIndex = createNode(Node.ELEMENT_NODE);
int elementChunk = elementNodeIndex >> CHUNK_SHIFT;
int elementIndex = elementNodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, elementName, elementChunk, elementIndex);
setChunkValue(fNodeURI, elementURI, elementChunk, elementIndex);
setChunkValue(fNodeValue, type, elementChunk, elementIndex);
// return node index
return elementNodeIndex;
| public int | createDeferredElement(java.lang.String elementName)
return createDeferredElement(null, elementName);
| public int | createDeferredElement(java.lang.String elementURI, java.lang.String elementName)
// create node
int elementNodeIndex = createNode(Node.ELEMENT_NODE);
int elementChunk = elementNodeIndex >> CHUNK_SHIFT;
int elementIndex = elementNodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, elementName, elementChunk, elementIndex);
setChunkValue(fNodeURI, elementURI, elementChunk, elementIndex);
// return node index
return elementNodeIndex;
| public int | createDeferredElementDefinition(java.lang.String elementName)Creates an element definition in the table.
// create node
int nodeIndex = createNode(NodeImpl.ELEMENT_DEFINITION_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, elementName, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredEntity(java.lang.String entityName, java.lang.String publicId, java.lang.String systemId, java.lang.String notationName, java.lang.String baseURI)Creates an entity in the table.
// create node
int nodeIndex = createNode(Node.ENTITY_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
// create extra data node
int extraDataIndex = createNode(Node.ENTITY_NODE);
int echunk = extraDataIndex >> CHUNK_SHIFT;
int eindex = extraDataIndex & CHUNK_MASK;
// save name, public id, system id, and notation name
setChunkValue(fNodeName, entityName, chunk, index);
setChunkValue(fNodeValue, publicId, chunk, index);
setChunkValue(fNodeURI, systemId, chunk, index);
setChunkIndex(fNodeExtra, extraDataIndex, chunk, index);
// set other values in the extra chunk
// notation
setChunkValue(fNodeName, notationName, echunk, eindex);
// version L3
setChunkValue(fNodeValue, null, echunk, eindex);
// encoding L3
setChunkValue(fNodeURI, null, echunk, eindex);
int extraDataIndex2 = createNode(Node.ENTITY_NODE);
int echunk2 = extraDataIndex2 >> CHUNK_SHIFT;
int eindex2 = extraDataIndex2 & CHUNK_MASK;
setChunkIndex(fNodeExtra, extraDataIndex2, echunk, eindex);
// baseURI
setChunkValue(fNodeName, baseURI, echunk2, eindex2);
// return node index
return nodeIndex;
| public int | createDeferredEntityReference(java.lang.String name, java.lang.String baseURI)Creates an entity reference node in the table.
// create node
int nodeIndex = createNode(Node.ENTITY_REFERENCE_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, name, chunk, index);
setChunkValue(fNodeValue, baseURI, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredNotation(java.lang.String notationName, java.lang.String publicId, java.lang.String systemId, java.lang.String baseURI)Creates a notation in the table.
// create node
int nodeIndex = createNode(Node.NOTATION_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
// create extra data node
int extraDataIndex = createNode(Node.NOTATION_NODE);
int echunk = extraDataIndex >> CHUNK_SHIFT;
int eindex = extraDataIndex & CHUNK_MASK;
// save name, public id, system id, and notation name
setChunkValue(fNodeName, notationName, chunk, index);
setChunkValue(fNodeValue, publicId, chunk, index);
setChunkValue(fNodeURI, systemId, chunk, index);
// in extra data node set baseURI value
setChunkIndex(fNodeExtra, extraDataIndex, chunk, index);
setChunkValue(fNodeName, baseURI, echunk, eindex);
// return node index
return nodeIndex;
| public int | createDeferredProcessingInstruction(java.lang.String target, java.lang.String data)Creates a processing instruction node in the table.
// create node
int nodeIndex = createNode(Node.PROCESSING_INSTRUCTION_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeName, target, chunk, index);
setChunkValue(fNodeValue, data, chunk, index);
// return node index
return nodeIndex;
| public int | createDeferredTextNode(java.lang.String data, boolean ignorableWhitespace)Creates a text node in the table.
// create node
int nodeIndex = createNode(Node.TEXT_NODE);
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
setChunkValue(fNodeValue, data, chunk, index);
// use extra to store ignorableWhitespace info
setChunkIndex(fNodeExtra, ignorableWhitespace ? 1 : 0, chunk, index);
// return node index
return nodeIndex;
| protected int | createNode(short nodeType)Creates a node of the specified type.
// ensure tables are large enough
int chunk = fNodeCount >> CHUNK_SHIFT;
int index = fNodeCount & CHUNK_MASK;
ensureCapacity(chunk);
// initialize node
setChunkIndex(fNodeType, nodeType, chunk, index);
// return node index number
return fNodeCount++;
| protected void | ensureCapacity(int chunk)Ensures that the internal tables are large enough.
if (fNodeType == null) {
// create buffers
fNodeType = new int[INITIAL_CHUNK_COUNT][];
fNodeName = new Object[INITIAL_CHUNK_COUNT][];
fNodeValue = new Object[INITIAL_CHUNK_COUNT][];
fNodeParent = new int[INITIAL_CHUNK_COUNT][];
fNodeLastChild = new int[INITIAL_CHUNK_COUNT][];
fNodePrevSib = new int[INITIAL_CHUNK_COUNT][];
fNodeURI = new Object[INITIAL_CHUNK_COUNT][];
fNodeExtra = new int[INITIAL_CHUNK_COUNT][];
}
else if (fNodeType.length <= chunk) {
// resize the tables
int newsize = chunk * 2;
int[][] newArray = new int[newsize][];
System.arraycopy(fNodeType, 0, newArray, 0, chunk);
fNodeType = newArray;
Object[][] newStrArray = new Object[newsize][];
System.arraycopy(fNodeName, 0, newStrArray, 0, chunk);
fNodeName = newStrArray;
newStrArray = new Object[newsize][];
System.arraycopy(fNodeValue, 0, newStrArray, 0, chunk);
fNodeValue = newStrArray;
newArray = new int[newsize][];
System.arraycopy(fNodeParent, 0, newArray, 0, chunk);
fNodeParent = newArray;
newArray = new int[newsize][];
System.arraycopy(fNodeLastChild, 0, newArray, 0, chunk);
fNodeLastChild = newArray;
newArray = new int[newsize][];
System.arraycopy(fNodePrevSib, 0, newArray, 0, chunk);
fNodePrevSib = newArray;
newStrArray = new Object[newsize][];
System.arraycopy(fNodeURI, 0, newStrArray, 0, chunk);
fNodeURI = newStrArray;
newArray = new int[newsize][];
System.arraycopy(fNodeExtra, 0, newArray, 0, chunk);
fNodeExtra = newArray;
}
else if (fNodeType[chunk] != null) {
// Done - there's sufficient capacity
return;
}
// create new chunks
createChunk(fNodeType, chunk);
createChunk(fNodeName, chunk);
createChunk(fNodeValue, chunk);
createChunk(fNodeParent, chunk);
createChunk(fNodeLastChild, chunk);
createChunk(fNodePrevSib, chunk);
createChunk(fNodeURI, chunk);
createChunk(fNodeExtra, chunk);
// Done
return;
| public java.lang.String | getAttribute(int elemIndex, java.lang.String name)Returns the attribute value of the given name.
if (elemIndex == -1 || name == null) {
return null;
}
int echunk = elemIndex >> CHUNK_SHIFT;
int eindex = elemIndex & CHUNK_MASK;
int attrIndex = getChunkIndex(fNodeExtra, echunk, eindex);
while (attrIndex != -1) {
int achunk = attrIndex >> CHUNK_SHIFT;
int aindex = attrIndex & CHUNK_MASK;
if (getChunkValue(fNodeName, achunk, aindex) == name) {
return getChunkValue(fNodeValue, achunk, aindex);
}
attrIndex = getChunkIndex(fNodePrevSib, achunk, aindex);
}
return null;
| private final int | getChunkIndex(int[][] data, int chunk, int index)Returns the specified value in the given data at the chunk and index.
return data[chunk] != null ? data[chunk][index] : -1;
| private final java.lang.String | getChunkValue(java.lang.Object[][] data, int chunk, int index)
return data[chunk] != null ? (String) data[chunk][index] : null;
| public java.lang.String | getDeferredEntityBaseURI(int entityIndex)
if (entityIndex != -1) {
int extraDataIndex = getNodeExtra(entityIndex, false);
extraDataIndex = getNodeExtra(extraDataIndex, false);
return getNodeName (extraDataIndex, false);
}
return null;
| public int | getLastChild(int nodeIndex)Returns the last child of the given node.
return getLastChild(nodeIndex, true);
| public int | getLastChild(int nodeIndex, boolean free)Returns the last child of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkIndex(fNodeLastChild, chunk, index)
: getChunkIndex(fNodeLastChild, chunk, index);
| boolean | getNamespacesEnabled()Returns the cached parser.getNamespaces() value.
return fNamespacesEnabled;
| public int | getNodeExtra(int nodeIndex)Returns the extra info of the given node.
Used by AttrImpl to store specified value (1 == true).
return getNodeExtra(nodeIndex, true);
| public int | getNodeExtra(int nodeIndex, boolean free)Returns the extra info of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkIndex(fNodeExtra, chunk, index)
: getChunkIndex(fNodeExtra, chunk, index);
| public int | getNodeIndex()Returns the node index.
return 0;
| public java.lang.String | getNodeName(int nodeIndex)Returns the name of the given node.
return getNodeName(nodeIndex, true);
| public java.lang.String | getNodeName(int nodeIndex, boolean free)Returns the name of the given node.
if (nodeIndex == -1) {
return null;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkValue(fNodeName, chunk, index)
: getChunkValue(fNodeName, chunk, index);
| public com.sun.org.apache.xerces.internal.dom.DeferredNode | getNodeObject(int nodeIndex)Instantiates the requested node object.
// is there anything to do?
if (nodeIndex == -1) {
return null;
}
// get node type
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
int type = getChunkIndex(fNodeType, chunk, index);
if (type != Node.TEXT_NODE && type != Node.CDATA_SECTION_NODE) {
clearChunkIndex(fNodeType, chunk, index);
}
// create new node
DeferredNode node = null;
switch (type) {
//
// Standard DOM node types
//
case Node.ATTRIBUTE_NODE: {
if (fNamespacesEnabled) {
node = new DeferredAttrNSImpl(this, nodeIndex);
} else {
node = new DeferredAttrImpl(this, nodeIndex);
}
break;
}
case Node.CDATA_SECTION_NODE: {
node = new DeferredCDATASectionImpl(this, nodeIndex);
break;
}
case Node.COMMENT_NODE: {
node = new DeferredCommentImpl(this, nodeIndex);
break;
}
// NOTE: Document fragments can never be "fast".
//
// The parser will never ask to create a document
// fragment during the parse. Document fragments
// are used by the application *after* the parse.
//
// case Node.DOCUMENT_FRAGMENT_NODE: { break; }
case Node.DOCUMENT_NODE: {
// this node is never "fast"
node = this;
break;
}
case Node.DOCUMENT_TYPE_NODE: {
node = new DeferredDocumentTypeImpl(this, nodeIndex);
// save the doctype node
docType = (DocumentTypeImpl)node;
break;
}
case Node.ELEMENT_NODE: {
if (DEBUG_IDS) {
System.out.println("getNodeObject(ELEMENT_NODE): "+nodeIndex);
}
// create node
if (fNamespacesEnabled) {
node = new DeferredElementNSImpl(this, nodeIndex);
} else {
node = new DeferredElementImpl(this, nodeIndex);
}
// save the document element node
if (docElement == null) {
docElement = (ElementImpl)node;
}
// check to see if this element needs to be
// registered for its ID attributes
if (fIdElement != null) {
int idIndex = binarySearch(fIdElement, 0,
fIdCount-1, nodeIndex);
while (idIndex != -1) {
if (DEBUG_IDS) {
System.out.println(" id index: "+idIndex);
System.out.println(" fIdName["+idIndex+
"]: "+fIdName[idIndex]);
}
// register ID
String name = fIdName[idIndex];
if (name != null) {
if (DEBUG_IDS) {
System.out.println(" name: "+name);
System.out.print("getNodeObject()#");
}
putIdentifier0(name, (Element)node);
fIdName[idIndex] = null;
}
// continue if there are more IDs for
// this element
if (idIndex + 1 < fIdCount &&
fIdElement[idIndex + 1] == nodeIndex) {
idIndex++;
}
else {
idIndex = -1;
}
}
}
break;
}
case Node.ENTITY_NODE: {
node = new DeferredEntityImpl(this, nodeIndex);
break;
}
case Node.ENTITY_REFERENCE_NODE: {
node = new DeferredEntityReferenceImpl(this, nodeIndex);
break;
}
case Node.NOTATION_NODE: {
node = new DeferredNotationImpl(this, nodeIndex);
break;
}
case Node.PROCESSING_INSTRUCTION_NODE: {
node = new DeferredProcessingInstructionImpl(this, nodeIndex);
break;
}
case Node.TEXT_NODE: {
node = new DeferredTextImpl(this, nodeIndex);
break;
}
//
// non-standard DOM node types
//
case NodeImpl.ELEMENT_DEFINITION_NODE: {
node = new DeferredElementDefinitionImpl(this, nodeIndex);
break;
}
default: {
throw new IllegalArgumentException("type: "+type);
}
} // switch node type
// store and return
if (node != null) {
return node;
}
// error
throw new IllegalArgumentException();
| public short | getNodeType(int nodeIndex)Returns the type of the given node.
return getNodeType(nodeIndex, true);
| public short | getNodeType(int nodeIndex, boolean free)Returns the type of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? (short)clearChunkIndex(fNodeType, chunk, index)
: (short)getChunkIndex(fNodeType, chunk, index);
| public java.lang.String | getNodeURI(int nodeIndex)Returns the URI of the given node.
return getNodeURI(nodeIndex, true);
| public java.lang.String | getNodeURI(int nodeIndex, boolean free)Returns the URI of the given node.
if (nodeIndex == -1) {
return null;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkValue(fNodeURI, chunk, index)
: getChunkValue(fNodeURI, chunk, index);
| public java.lang.String | getNodeValue(int nodeIndex)Returns the value of the given node.
return getNodeValue(nodeIndex, true);
| public java.lang.String | getNodeValue(int nodeIndex, boolean free)Returns the value of the given node.
if (nodeIndex == -1) {
return null;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkValue(fNodeValue, chunk, index)
: getChunkValue(fNodeValue, chunk, index);
| private final java.lang.String | getNodeValue(int chunk, int index)
Object data = fNodeValue[chunk][index];
if (data == null){
return null;
}
else if (data instanceof String){
return (String)data;
}
else {
// type information
return data.toString();
}
| public java.lang.String | getNodeValueString(int nodeIndex)Returns the real value of the given node.
return getNodeValueString(nodeIndex, true);
| public java.lang.String | getNodeValueString(int nodeIndex, boolean free)Returns the real value of the given node.
if (nodeIndex == -1) {
return null;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
String value = free ? clearChunkValue(fNodeValue, chunk, index)
: getChunkValue(fNodeValue, chunk, index);
if (value == null) {
return null;
}
int type = getChunkIndex(fNodeType, chunk, index);
if (type == Node.TEXT_NODE) {
int prevSib = getRealPrevSibling(nodeIndex);
if (prevSib != -1 &&
getNodeType(prevSib, false) == Node.TEXT_NODE) {
// append data that is stored in fNodeValue
// REVISIT: for text nodes it works differently than for CDATA
// nodes.
fStrChunks.addElement(value);
do {
// go in reverse order: find last child, then
// its previous sibling, etc
chunk = prevSib >> CHUNK_SHIFT;
index = prevSib & CHUNK_MASK;
value = getChunkValue(fNodeValue, chunk, index);
fStrChunks.addElement(value);
prevSib = getChunkIndex(fNodePrevSib, chunk, index);
if (prevSib == -1) {
break;
}
} while (getNodeType(prevSib, false) == Node.TEXT_NODE);
int chunkCount = fStrChunks.size();
// add to the buffer in the correct order.
for (int i = chunkCount - 1; i >= 0; i--) {
fBufferStr.append((String)fStrChunks.elementAt(i));
}
value = fBufferStr.toString();
fStrChunks.removeAllElements();
fBufferStr.setLength(0);
return value;
}
}
else if (type == Node.CDATA_SECTION_NODE) {
// find if any other data stored in children
int child = getLastChild(nodeIndex, false);
if (child !=-1) {
// append data that is stored in fNodeValue
fBufferStr.append(value);
while (child !=-1) {
// go in reverse order: find last child, then
// its previous sibling, etc
chunk = child >> CHUNK_SHIFT;
index = child & CHUNK_MASK;
value = getChunkValue(fNodeValue, chunk, index);
fStrChunks.addElement(value);
child = getChunkIndex(fNodePrevSib, chunk, index);
}
// add to the buffer in the correct order.
for (int i=fStrChunks.size()-1; i>=0; i--) {
fBufferStr.append((String)fStrChunks.elementAt(i));
}
value = fBufferStr.toString();
fStrChunks.setSize(0);
fBufferStr.setLength(0);
return value;
}
}
return value;
| public int | getParentNode(int nodeIndex)Returns the parent node of the given node.
Calling this method does not free the parent index.
return getParentNode(nodeIndex, false);
| public int | getParentNode(int nodeIndex, boolean free)Returns the parent node of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkIndex(fNodeParent, chunk, index)
: getChunkIndex(fNodeParent, chunk, index);
| public int | getPrevSibling(int nodeIndex)Returns the prev sibling of the given node.
This is post-normalization of Text Nodes.
return getPrevSibling(nodeIndex, true);
| public int | getPrevSibling(int nodeIndex, boolean free)Returns the prev sibling of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
int type = getChunkIndex(fNodeType, chunk, index);
if (type == Node.TEXT_NODE) {
do {
nodeIndex = getChunkIndex(fNodePrevSib, chunk, index);
if (nodeIndex == -1) {
break;
}
chunk = nodeIndex >> CHUNK_SHIFT;
index = nodeIndex & CHUNK_MASK;
type = getChunkIndex(fNodeType, chunk, index);
} while (type == Node.TEXT_NODE);
}
else {
nodeIndex = getChunkIndex(fNodePrevSib, chunk, index);
}
return nodeIndex;
| public int | getRealPrevSibling(int nodeIndex)Returns the real prev sibling of the given node,
directly from the data structures. Used by TextImpl#getNodeValue()
to normalize values.
return getRealPrevSibling(nodeIndex, true);
| public int | getRealPrevSibling(int nodeIndex, boolean free)Returns the real prev sibling of the given node.
if (nodeIndex == -1) {
return -1;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
return free ? clearChunkIndex(fNodePrevSib, chunk, index)
: getChunkIndex(fNodePrevSib, chunk, index);
| public org.w3c.dom.TypeInfo | getTypeInfo(int nodeIndex)Clears the type info that is stored in the fNodeValue array
if (nodeIndex == -1) {
return null;
}
int chunk = nodeIndex >> CHUNK_SHIFT;
int index = nodeIndex & CHUNK_MASK;
TypeInfo value = (TypeInfo)(fNodeValue[chunk] != null ? fNodeValue[chunk][index] : null);
if (value != null) {
fNodeValue[chunk][index] = null;
RefCount c = (RefCount) fNodeValue[chunk][CHUNK_SIZE];
c.fCount--;
if (c.fCount == 0) {
fNodeValue[chunk] = null;
}
}
return value;
| public int | insertBefore(int parentIndex, int newChildIndex, int refChildIndex)Inserts a child before the specified node in the table.
if (refChildIndex == -1) {
appendChild(parentIndex, newChildIndex);
return newChildIndex;
}
int nchunk = newChildIndex >> CHUNK_SHIFT;
int nindex = newChildIndex & CHUNK_MASK;
int rchunk = refChildIndex >> CHUNK_SHIFT;
int rindex = refChildIndex & CHUNK_MASK;
int previousIndex = getChunkIndex(fNodePrevSib, rchunk, rindex);
setChunkIndex(fNodePrevSib, newChildIndex, rchunk, rindex);
setChunkIndex(fNodePrevSib, previousIndex, nchunk, nindex);
return newChildIndex;
| public int | lookupElementDefinition(java.lang.String elementName)Returns the index of the element definition in the table
with the specified name index, or -1 if no such definition
exists.
if (fNodeCount > 1) {
// find doctype
int docTypeIndex = -1;
int nchunk = 0;
int nindex = 0;
for (int index = getChunkIndex(fNodeLastChild, nchunk, nindex);
index != -1;
index = getChunkIndex(fNodePrevSib, nchunk, nindex)) {
nchunk = index >> CHUNK_SHIFT;
nindex = index & CHUNK_MASK;
if (getChunkIndex(fNodeType, nchunk, nindex) == Node.DOCUMENT_TYPE_NODE) {
docTypeIndex = index;
break;
}
}
// find element definition
if (docTypeIndex == -1) {
return -1;
}
nchunk = docTypeIndex >> CHUNK_SHIFT;
nindex = docTypeIndex & CHUNK_MASK;
for (int index = getChunkIndex(fNodeLastChild, nchunk, nindex);
index != -1;
index = getChunkIndex(fNodePrevSib, nchunk, nindex)) {
nchunk = index >> CHUNK_SHIFT;
nindex = index & CHUNK_MASK;
if (getChunkIndex(fNodeType, nchunk, nindex) ==
NodeImpl.ELEMENT_DEFINITION_NODE
&& getChunkValue(fNodeName, nchunk, nindex) == elementName) {
return index;
}
}
}
return -1;
| public void | print()Prints out the tables.
if (DEBUG_PRINT_REF_COUNTS) {
System.out.print("num\t");
System.out.print("type\t");
System.out.print("name\t");
System.out.print("val\t");
System.out.print("par\t");
System.out.print("lch\t");
System.out.print("psib");
System.out.println();
for (int i = 0; i < fNodeType.length; i++) {
if (fNodeType[i] != null) {
// separator
System.out.print("--------");
System.out.print("--------");
System.out.print("--------");
System.out.print("--------");
System.out.print("--------");
System.out.print("--------");
System.out.print("--------");
System.out.println();
// ref count
System.out.print(i);
System.out.print('\t");
switch (fNodeType[i][CHUNK_SIZE]) {
case DocumentImpl.ELEMENT_DEFINITION_NODE: { System.out.print("EDef"); break; }
case Node.DOCUMENT_NODE: { System.out.print("Doc"); break; }
case Node.DOCUMENT_TYPE_NODE: { System.out.print("DType"); break; }
case Node.COMMENT_NODE: { System.out.print("Com"); break; }
case Node.PROCESSING_INSTRUCTION_NODE: { System.out.print("PI"); break; }
case Node.ELEMENT_NODE: { System.out.print("Elem"); break; }
case Node.ENTITY_NODE: { System.out.print("Ent"); break; }
case Node.ENTITY_REFERENCE_NODE: { System.out.print("ERef"); break; }
case Node.TEXT_NODE: { System.out.print("Text"); break; }
case Node.ATTRIBUTE_NODE: { System.out.print("Attr"); break; }
case DeferredNode.TYPE_NODE: { System.out.print("TypeInfo"); break; }
default: { System.out.print("?"+fNodeType[i][CHUNK_SIZE]); }
}
System.out.print('\t");
System.out.print(fNodeName[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodeValue[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodeURI[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodeParent[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodeLastChild[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodePrevSib[i][CHUNK_SIZE]);
System.out.print('\t");
System.out.print(fNodeExtra[i][CHUNK_SIZE]);
System.out.println();
}
}
}
if (DEBUG_PRINT_TABLES) {
// This assumes that the document is small
System.out.println("# start table");
for (int i = 0; i < fNodeCount; i++) {
int chunk = i >> CHUNK_SHIFT;
int index = i & CHUNK_MASK;
if (i % 10 == 0) {
System.out.print("num\t");
System.out.print("type\t");
System.out.print("name\t");
System.out.print("val\t");
System.out.print("uri\t");
System.out.print("par\t");
System.out.print("lch\t");
System.out.print("psib\t");
System.out.print("xtra");
System.out.println();
}
System.out.print(i);
System.out.print('\t");
switch (getChunkIndex(fNodeType, chunk, index)) {
case DocumentImpl.ELEMENT_DEFINITION_NODE: { System.out.print("EDef"); break; }
case Node.DOCUMENT_NODE: { System.out.print("Doc"); break; }
case Node.DOCUMENT_TYPE_NODE: { System.out.print("DType"); break; }
case Node.COMMENT_NODE: { System.out.print("Com"); break; }
case Node.PROCESSING_INSTRUCTION_NODE: { System.out.print("PI"); break; }
case Node.ELEMENT_NODE: { System.out.print("Elem"); break; }
case Node.ENTITY_NODE: { System.out.print("Ent"); break; }
case Node.ENTITY_REFERENCE_NODE: { System.out.print("ERef"); break; }
case Node.TEXT_NODE: { System.out.print("Text"); break; }
case Node.ATTRIBUTE_NODE: { System.out.print("Attr"); break; }
case DeferredNode.TYPE_NODE: { System.out.print("TypeInfo"); break; }
default: { System.out.print("?"+getChunkIndex(fNodeType, chunk, index)); }
}
System.out.print('\t");
System.out.print(getChunkValue(fNodeName, chunk, index));
System.out.print('\t");
System.out.print(getNodeValue(chunk, index));
System.out.print('\t");
System.out.print(getChunkValue(fNodeURI, chunk, index));
System.out.print('\t");
System.out.print(getChunkIndex(fNodeParent, chunk, index));
System.out.print('\t");
System.out.print(getChunkIndex(fNodeLastChild, chunk, index));
System.out.print('\t");
System.out.print(getChunkIndex(fNodePrevSib, chunk, index));
System.out.print('\t");
System.out.print(getChunkIndex(fNodeExtra, chunk, index));
System.out.println();
}
System.out.println("# end table");
}
| private static void | print(int[] values, int start, int end, int middle, int target)Prints the ID array.
if (DEBUG_IDS) {
System.out.print(start);
System.out.print(" [");
for (int i = start; i < end; i++) {
if (middle == i) {
System.out.print("!");
}
System.out.print(values[i]);
if (values[i] == target) {
System.out.print("*");
}
if (i < end - 1) {
System.out.print(" ");
}
}
System.out.println("] "+end);
}
| public void | putIdentifier(java.lang.String name, int elementNodeIndex)Registers an identifier name with a specified element node.
if (DEBUG_IDS) {
System.out.println("putIdentifier(" + name + ", "
+ elementNodeIndex + ')" + " // " +
getChunkValue(fNodeName,
elementNodeIndex >> CHUNK_SHIFT,
elementNodeIndex & CHUNK_MASK));
}
// initialize arrays
if (fIdName == null) {
fIdName = new String[64];
fIdElement = new int[64];
}
// resize arrays
if (fIdCount == fIdName.length) {
String idName[] = new String[fIdCount * 2];
System.arraycopy(fIdName, 0, idName, 0, fIdCount);
fIdName = idName;
int idElement[] = new int[idName.length];
System.arraycopy(fIdElement, 0, idElement, 0, fIdCount);
fIdElement = idElement;
}
// store identifier
fIdName[fIdCount] = name;
fIdElement[fIdCount] = elementNodeIndex;
fIdCount++;
| private final void | putIdentifier0(java.lang.String idName, org.w3c.dom.Element element)This version of putIdentifier is needed to avoid fluffing
all of the paths to ID attributes when a node object is
created that contains an ID attribute.
if (DEBUG_IDS) {
System.out.println("putIdentifier0("+
idName+", "+
element+')");
}
// create hashtable
if (identifiers == null) {
identifiers = new java.util.Hashtable();
}
// save ID and its associated element
identifiers.put(idName, element);
| public void | setAsLastChild(int parentIndex, int childIndex)Sets the last child of the parentIndex to childIndex.
int pchunk = parentIndex >> CHUNK_SHIFT;
int pindex = parentIndex & CHUNK_MASK;
int chunk = childIndex >> CHUNK_SHIFT;
int index = childIndex & CHUNK_MASK;
setChunkIndex(fNodeLastChild, childIndex, pchunk, pindex);
| public int | setAttributeNode(int elemIndex, int attrIndex)Adds an attribute node to the specified element.
int echunk = elemIndex >> CHUNK_SHIFT;
int eindex = elemIndex & CHUNK_MASK;
int achunk = attrIndex >> CHUNK_SHIFT;
int aindex = attrIndex & CHUNK_MASK;
// see if this attribute is already here
String attrName = getChunkValue(fNodeName, achunk, aindex);
int oldAttrIndex = getChunkIndex(fNodeExtra, echunk, eindex);
int nextIndex = -1;
int oachunk = -1;
int oaindex = -1;
while (oldAttrIndex != -1) {
oachunk = oldAttrIndex >> CHUNK_SHIFT;
oaindex = oldAttrIndex & CHUNK_MASK;
String oldAttrName = getChunkValue(fNodeName, oachunk, oaindex);
if (oldAttrName.equals(attrName)) {
break;
}
nextIndex = oldAttrIndex;
oldAttrIndex = getChunkIndex(fNodePrevSib, oachunk, oaindex);
}
// remove old attribute
if (oldAttrIndex != -1) {
// patch links
int prevIndex = getChunkIndex(fNodePrevSib, oachunk, oaindex);
if (nextIndex == -1) {
setChunkIndex(fNodeExtra, prevIndex, echunk, eindex);
}
else {
int pchunk = nextIndex >> CHUNK_SHIFT;
int pindex = nextIndex & CHUNK_MASK;
setChunkIndex(fNodePrevSib, prevIndex, pchunk, pindex);
}
// remove connections to siblings
clearChunkIndex(fNodeType, oachunk, oaindex);
clearChunkValue(fNodeName, oachunk, oaindex);
clearChunkValue(fNodeValue, oachunk, oaindex);
clearChunkIndex(fNodeParent, oachunk, oaindex);
clearChunkIndex(fNodePrevSib, oachunk, oaindex);
int attrTextIndex =
clearChunkIndex(fNodeLastChild, oachunk, oaindex);
int atchunk = attrTextIndex >> CHUNK_SHIFT;
int atindex = attrTextIndex & CHUNK_MASK;
clearChunkIndex(fNodeType, atchunk, atindex);
clearChunkValue(fNodeValue, atchunk, atindex);
clearChunkIndex(fNodeParent, atchunk, atindex);
clearChunkIndex(fNodeLastChild, atchunk, atindex);
}
// add new attribute
int prevIndex = getChunkIndex(fNodeExtra, echunk, eindex);
setChunkIndex(fNodeExtra, attrIndex, echunk, eindex);
setChunkIndex(fNodePrevSib, prevIndex, achunk, aindex);
// return
return oldAttrIndex;
| private final int | setChunkIndex(int[][] data, int value, int chunk, int index)Sets the specified value in the given of data at the chunk and index.
if (value == -1) {
return clearChunkIndex(data, chunk, index);
}
int ovalue = data[chunk][index];
if (ovalue == -1) {
data[chunk][CHUNK_SIZE]++;
}
data[chunk][index] = value;
return ovalue;
| private final java.lang.String | setChunkValue(java.lang.Object[][] data, java.lang.Object value, int chunk, int index)
if (value == null) {
return clearChunkValue(data, chunk, index);
}
String ovalue = (String) data[chunk][index];
if (ovalue == null) {
RefCount c = (RefCount) data[chunk][CHUNK_SIZE];
c.fCount++;
}
data[chunk][index] = value;
return ovalue;
| public int | setDeferredAttribute(int elementNodeIndex, java.lang.String attrName, java.lang.String attrURI, java.lang.String attrValue, boolean specified, boolean id, org.w3c.dom.TypeInfo type)This method is used by the DOMParser to create attributes.
// create attribute
int attrNodeIndex = createDeferredAttribute(attrName, attrURI, attrValue, specified);
int attrChunk = attrNodeIndex >> CHUNK_SHIFT;
int attrIndex = attrNodeIndex & CHUNK_MASK;
// set attribute's parent to element
setChunkIndex(fNodeParent, elementNodeIndex, attrChunk, attrIndex);
int elementChunk = elementNodeIndex >> CHUNK_SHIFT;
int elementIndex = elementNodeIndex & CHUNK_MASK;
// get element's last attribute
int lastAttrNodeIndex = getChunkIndex(fNodeExtra, elementChunk, elementIndex);
if (lastAttrNodeIndex != 0) {
int lastAttrChunk = lastAttrNodeIndex >> CHUNK_SHIFT;
int lastAttrIndex = lastAttrNodeIndex & CHUNK_MASK;
// add link from new attribute to last attribute
setChunkIndex(fNodePrevSib, lastAttrNodeIndex, attrChunk, attrIndex);
}
// add link from element to new last attribute
setChunkIndex(fNodeExtra, attrNodeIndex, elementChunk, elementIndex);
int extra = getChunkIndex(fNodeExtra, attrChunk, attrIndex);
if (id) {
extra = extra | ID;
setChunkIndex(fNodeExtra, extra, attrChunk, attrIndex);
String value = getChunkValue(fNodeValue, attrChunk, attrIndex);
putIdentifier(value, elementNodeIndex);
}
// store type information
if (type != null) {
int extraDataIndex = createNode(DeferredNode.TYPE_NODE);
int echunk = extraDataIndex >> CHUNK_SHIFT;
int eindex = extraDataIndex & CHUNK_MASK;
setChunkIndex(fNodeLastChild, extraDataIndex, attrChunk, attrIndex);
setChunkValue(fNodeValue, type, echunk, eindex);
}
// return node index
return attrNodeIndex;
| public int | setDeferredAttribute(int elementNodeIndex, java.lang.String attrName, java.lang.String attrURI, java.lang.String attrValue, boolean specified)
// create attribute
int attrNodeIndex = createDeferredAttribute(attrName, attrURI,
attrValue, specified);
int attrChunk = attrNodeIndex >> CHUNK_SHIFT;
int attrIndex = attrNodeIndex & CHUNK_MASK;
// set attribute's parent to element
setChunkIndex(fNodeParent, elementNodeIndex, attrChunk, attrIndex);
int elementChunk = elementNodeIndex >> CHUNK_SHIFT;
int elementIndex = elementNodeIndex & CHUNK_MASK;
// get element's last attribute
int lastAttrNodeIndex = getChunkIndex(fNodeExtra,
elementChunk, elementIndex);
if (lastAttrNodeIndex != 0) {
int lastAttrChunk = lastAttrNodeIndex >> CHUNK_SHIFT;
int lastAttrIndex = lastAttrNodeIndex & CHUNK_MASK;
// add link from new attribute to last attribute
setChunkIndex(fNodePrevSib, lastAttrNodeIndex,
attrChunk, attrIndex);
}
// add link from element to new last attribute
setChunkIndex(fNodeExtra, attrNodeIndex,
elementChunk, elementIndex);
// return node index
return attrNodeIndex;
| public void | setEntityInfo(int currentEntityDecl, java.lang.String version, java.lang.String encoding)
int eNodeIndex = getNodeExtra(currentEntityDecl, false);
if (eNodeIndex !=-1) {
int echunk = eNodeIndex >> CHUNK_SHIFT;
int eindex = eNodeIndex & CHUNK_MASK;
setChunkValue(fNodeValue, version, echunk, eindex);
setChunkValue(fNodeURI, encoding, echunk, eindex);
}
| public void | setIdAttribute(int attrIndex)Sets type of attribute
int chunk = attrIndex >> CHUNK_SHIFT;
int index = attrIndex & CHUNK_MASK;
int extra = getChunkIndex(fNodeExtra, chunk, index);
extra = extra | ID;
setChunkIndex(fNodeExtra, extra, chunk, index);
| public void | setIdAttributeNode(int elemIndex, int attrIndex)Adds an attribute node to the specified element.
int chunk = attrIndex >> CHUNK_SHIFT;
int index = attrIndex & CHUNK_MASK;
int extra = getChunkIndex(fNodeExtra, chunk, index);
extra = extra | ID;
setChunkIndex(fNodeExtra, extra, chunk, index);
String value = getChunkValue(fNodeValue, chunk, index);
putIdentifier(value, elemIndex);
| public void | setInputEncoding(int currentEntityDecl, java.lang.String value)DOM Internal
An attribute specifying the actual encoding of this document. This is
null otherwise.
This attribute represents the property [character encoding scheme]
defined in .
// get first extra data chunk
int nodeIndex = getNodeExtra(currentEntityDecl, false);
// get second extra data chunk
int extraDataIndex = getNodeExtra(nodeIndex, false);
int echunk = extraDataIndex >> CHUNK_SHIFT;
int eindex = extraDataIndex & CHUNK_MASK;
setChunkValue(fNodeValue, value, echunk, eindex);
| public void | setInternalSubset(int doctypeIndex, java.lang.String subset)
int chunk = doctypeIndex >> CHUNK_SHIFT;
int index = doctypeIndex & CHUNK_MASK;
// create extra data node to store internal subset
int extraDataIndex = createNode(Node.DOCUMENT_TYPE_NODE);
int echunk = extraDataIndex >> CHUNK_SHIFT;
int eindex = extraDataIndex & CHUNK_MASK;
setChunkIndex(fNodeExtra, extraDataIndex, chunk, index);
setChunkValue(fNodeValue, subset, echunk, eindex);
| void | setNamespacesEnabled(boolean enable)
fNamespacesEnabled = enable;
| protected void | synchronizeChildren()Synchronizes the node's children with the internal structure.
Fluffing the children at once solves a lot of work to keep
the two structures in sync. The problem gets worse when
editing the tree -- this makes it a lot easier.
if (needsSyncData()) {
synchronizeData();
/*
* when we have elements with IDs this method is being recursively
* called from synchronizeData, in which case we've already gone
* through the following and we can now simply stop here.
*/
if (!needsSyncChildren()) {
return;
}
}
// we don't want to generate any event for this so turn them off
boolean orig = mutationEvents;
mutationEvents = false;
// no need to sync in the future
needsSyncChildren(false);
getNodeType(0);
// create children and link them as siblings
ChildNode first = null;
ChildNode last = null;
for (int index = getLastChild(0);
index != -1;
index = getPrevSibling(index)) {
ChildNode node = (ChildNode)getNodeObject(index);
if (last == null) {
last = node;
}
else {
first.previousSibling = node;
}
node.ownerNode = this;
node.isOwned(true);
node.nextSibling = first;
first = node;
// save doctype and document type
int type = node.getNodeType();
if (type == Node.ELEMENT_NODE) {
docElement = (ElementImpl)node;
}
else if (type == Node.DOCUMENT_TYPE_NODE) {
docType = (DocumentTypeImpl)node;
}
}
if (first != null) {
firstChild = first;
first.isFirstChild(true);
lastChild(last);
}
// set mutation events flag back to its original value
mutationEvents = orig;
| protected final void | synchronizeChildren(com.sun.org.apache.xerces.internal.dom.AttrImpl a, int nodeIndex)Synchronizes the node's children with the internal structure.
Fluffing the children at once solves a lot of work to keep
the two structures in sync. The problem gets worse when
editing the tree -- this makes it a lot easier.
This is not directly used in this class but this method is
here so that it can be shared by all deferred subclasses of AttrImpl.
// we don't want to generate any event for this so turn them off
boolean orig = getMutationEvents();
setMutationEvents(false);
// no need to sync in the future
a.needsSyncChildren(false);
// create children and link them as siblings or simply store the value
// as a String if all we have is one piece of text
int last = getLastChild(nodeIndex);
int prev = getPrevSibling(last);
if (prev == -1) {
a.value = getNodeValueString(nodeIndex);
a.hasStringValue(true);
}
else {
ChildNode firstNode = null;
ChildNode lastNode = null;
for (int index = last; index != -1;
index = getPrevSibling(index)) {
ChildNode node = (ChildNode) getNodeObject(index);
if (lastNode == null) {
lastNode = node;
}
else {
firstNode.previousSibling = node;
}
node.ownerNode = a;
node.isOwned(true);
node.nextSibling = firstNode;
firstNode = node;
}
if (lastNode != null) {
a.value = firstNode; // firstChild = firstNode
firstNode.isFirstChild(true);
a.lastChild(lastNode);
}
a.hasStringValue(false);
}
// set mutation events flag back to its original value
setMutationEvents(orig);
| protected final void | synchronizeChildren(com.sun.org.apache.xerces.internal.dom.ParentNode p, int nodeIndex)Synchronizes the node's children with the internal structure.
Fluffing the children at once solves a lot of work to keep
the two structures in sync. The problem gets worse when
editing the tree -- this makes it a lot easier.
This is not directly used in this class but this method is
here so that it can be shared by all deferred subclasses of ParentNode.
// we don't want to generate any event for this so turn them off
boolean orig = getMutationEvents();
setMutationEvents(false);
// no need to sync in the future
p.needsSyncChildren(false);
// create children and link them as siblings
ChildNode firstNode = null;
ChildNode lastNode = null;
for (int index = getLastChild(nodeIndex);
index != -1;
index = getPrevSibling(index)) {
ChildNode node = (ChildNode) getNodeObject(index);
if (lastNode == null) {
lastNode = node;
}
else {
firstNode.previousSibling = node;
}
node.ownerNode = p;
node.isOwned(true);
node.nextSibling = firstNode;
firstNode = node;
}
if (lastNode != null) {
p.firstChild = firstNode;
firstNode.isFirstChild(true);
p.lastChild(lastNode);
}
// set mutation events flag back to its original value
setMutationEvents(orig);
| protected void | synchronizeData()Synchronizes the node's data.
// no need to sync in the future
needsSyncData(false);
// fluff up enough nodes to fill identifiers hash
if (fIdElement != null) {
// REVISIT: There has to be a more efficient way of
// doing this. But keep in mind that the
// tree can have been altered and re-ordered
// before all of the element nodes with ID
// attributes have been registered. For now
// this is reasonable and safe. -Ac
IntVector path = new IntVector();
for (int i = 0; i < fIdCount; i++) {
// ignore if it's already been registered
int elementNodeIndex = fIdElement[i];
String idName = fIdName[i];
if (idName == null) {
continue;
}
// find path from this element to the root
path.removeAllElements();
int index = elementNodeIndex;
do {
path.addElement(index);
int pchunk = index >> CHUNK_SHIFT;
int pindex = index & CHUNK_MASK;
index = getChunkIndex(fNodeParent, pchunk, pindex);
} while (index != -1);
// Traverse path (backwards), fluffing the elements
// along the way. When this loop finishes, "place"
// will contain the reference to the element node
// we're interested in. -Ac
Node place = this;
for (int j = path.size() - 2; j >= 0; j--) {
index = path.elementAt(j);
Node child = place.getLastChild();
while (child != null) {
if (child instanceof DeferredNode) {
int nodeIndex =
((DeferredNode)child).getNodeIndex();
if (nodeIndex == index) {
place = child;
break;
}
}
child = child.getPreviousSibling();
}
}
// register the element
Element element = (Element)place;
putIdentifier0(idName, element);
fIdName[i] = null;
// see if there are more IDs on this element
while (i + 1 < fIdCount &&
fIdElement[i + 1] == elementNodeIndex) {
idName = fIdName[++i];
if (idName == null) {
continue;
}
putIdentifier0(idName, element);
}
}
} // if identifiers
|
|