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/*
 * Copyright 1999-2005 The Apache Software Foundation.
 *
 * Licensed under the Apache License, Version 2.0 (the "License");
 * you may not use this file except in compliance with the License.
 * You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
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package jdk8u.jaxp.org.apache.xerces.external.dom;

import java.util.Vector;

import org.w3c.dom.CharacterData;
import org.w3c.dom.DOMException;
import org.w3c.dom.DocumentFragment;
import org.w3c.dom.Node;
import org.w3c.dom.ranges.Range;
import org.w3c.dom.ranges.RangeException;


/** The RangeImpl class implements the org.w3c.dom.range.Range interface.
 *  

Please see the API documentation for the interface classes * and use the interfaces in your client programs. * * @xerces.internal * */ public class RangeImpl implements Range { // // Constants // // // Data // DocumentImpl fDocument; Node fStartContainer; Node fEndContainer; int fStartOffset; int fEndOffset; boolean fIsCollapsed; boolean fDetach = false; Node fInsertNode = null; Node fDeleteNode = null; Node fSplitNode = null; // Was the Node inserted from the Range or the Document boolean fInsertedFromRange = false; /** The constructor. Clients must use DocumentRange.createRange(), * because it registers the Range with the document, so it can * be fixed-up. */ public RangeImpl(DocumentImpl document) { fDocument = document; fStartContainer = document; fEndContainer = document; fStartOffset = 0; fEndOffset = 0; fDetach = false; } public Node getStartContainer() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } return fStartContainer; } public int getStartOffset() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } return fStartOffset; } public Node getEndContainer() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } return fEndContainer; } public int getEndOffset() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } return fEndOffset; } public boolean getCollapsed() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } return (fStartContainer == fEndContainer && fStartOffset == fEndOffset); } public Node getCommonAncestorContainer() { if ( fDetach ) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } Vector startV = new Vector(); Node node; for (node=fStartContainer; node != null; node=node.getParentNode()) { startV.addElement(node); } Vector endV = new Vector(); for (node=fEndContainer; node != null; node=node.getParentNode()) { endV.addElement(node); } int s = startV.size()-1; int e = endV.size()-1; Object result = null; while (s>=0 && e>=0) { if (startV.elementAt(s) == endV.elementAt(e)) { result = startV.elementAt(s); } else { break; } --s; --e; } return (Node)result; } public void setStart(Node refNode, int offset) throws RangeException, DOMException { if (fDocument.errorChecking) { if ( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !isLegalContainer(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } checkIndex(refNode, offset); fStartContainer = refNode; fStartOffset = offset; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(true); } } public void setEnd(Node refNode, int offset) throws RangeException, DOMException { if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !isLegalContainer(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } checkIndex(refNode, offset); fEndContainer = refNode; fEndOffset = offset; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(false); } } public void setStartBefore(Node refNode) throws RangeException { if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !hasLegalRootContainer(refNode) || !isLegalContainedNode(refNode) ) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } fStartContainer = refNode.getParentNode(); int i = 0; for (Node n = refNode; n!=null; n = n.getPreviousSibling()) { i++; } fStartOffset = i-1; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(true); } } public void setStartAfter(Node refNode) throws RangeException { if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !hasLegalRootContainer(refNode) || !isLegalContainedNode(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } fStartContainer = refNode.getParentNode(); int i = 0; for (Node n = refNode; n!=null; n = n.getPreviousSibling()) { i++; } fStartOffset = i; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(true); } } public void setEndBefore(Node refNode) throws RangeException { if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !hasLegalRootContainer(refNode) || !isLegalContainedNode(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } fEndContainer = refNode.getParentNode(); int i = 0; for (Node n = refNode; n!=null; n = n.getPreviousSibling()) { i++; } fEndOffset = i-1; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(false); } } public void setEndAfter(Node refNode) throws RangeException { if (fDocument.errorChecking) { if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !hasLegalRootContainer(refNode) || !isLegalContainedNode(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } fEndContainer = refNode.getParentNode(); int i = 0; for (Node n = refNode; n!=null; n = n.getPreviousSibling()) { i++; } fEndOffset = i; // If one boundary-point of a Range is set to have a root container // other // than the current one for the Range, the Range should be collapsed to // the new position. // The start position of a Range should never be after the end position. if (getCommonAncestorContainer() == null || (fStartContainer == fEndContainer && fEndOffset < fStartOffset)) { collapse(false); } } public void collapse(boolean toStart) { if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if (toStart) { fEndContainer = fStartContainer; fEndOffset = fStartOffset; } else { fStartContainer = fEndContainer; fStartOffset = fEndOffset; } } public void selectNode(Node refNode) throws RangeException { if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !isLegalContainer( refNode.getParentNode() ) || !isLegalContainedNode( refNode ) ) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } Node parent = refNode.getParentNode(); if (parent != null ) // REVIST: what to do if it IS null? { fStartContainer = parent; fEndContainer = parent; int i = 0; for (Node n = refNode; n!=null; n = n.getPreviousSibling()) { i++; } fStartOffset = i-1; fEndOffset = fStartOffset+1; } } public void selectNodeContents(Node refNode) throws RangeException { if (fDocument.errorChecking) { if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( !isLegalContainer(refNode)) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } if ( fDocument != refNode.getOwnerDocument() && fDocument != refNode) { throw new DOMException( DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } fStartContainer = refNode; fEndContainer = refNode; Node first = refNode.getFirstChild(); fStartOffset = 0; if (first == null) { fEndOffset = 0; } else { int i = 0; for (Node n = first; n!=null; n = n.getNextSibling()) { i++; } fEndOffset = i; } } public short compareBoundaryPoints(short how, Range sourceRange) throws DOMException { if (fDocument.errorChecking) { if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } // WRONG_DOCUMENT_ERR: Raised if the two Ranges are not in the same Document or DocumentFragment. if ((fDocument != sourceRange.getStartContainer().getOwnerDocument() && fDocument != sourceRange.getStartContainer() && sourceRange.getStartContainer() != null) || (fDocument != sourceRange.getEndContainer().getOwnerDocument() && fDocument != sourceRange.getEndContainer() && sourceRange.getStartContainer() != null)) { throw new DOMException(DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage( DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } } Node endPointA; Node endPointB; int offsetA; int offsetB; if (how == START_TO_START) { endPointA = sourceRange.getStartContainer(); endPointB = fStartContainer; offsetA = sourceRange.getStartOffset(); offsetB = fStartOffset; } else if (how == START_TO_END) { endPointA = sourceRange.getStartContainer(); endPointB = fEndContainer; offsetA = sourceRange.getStartOffset(); offsetB = fEndOffset; } else if (how == END_TO_START) { endPointA = sourceRange.getEndContainer(); endPointB = fStartContainer; offsetA = sourceRange.getEndOffset(); offsetB = fStartOffset; } else { endPointA = sourceRange.getEndContainer(); endPointB = fEndContainer; offsetA = sourceRange.getEndOffset(); offsetB = fEndOffset; } // The DOM Spec outlines four cases that need to be tested // to compare two range boundary points: // case 1: same container // case 2: Child C of container A is ancestor of B // case 3: Child C of container B is ancestor of A // case 4: preorder traversal of context tree. // case 1: same container if (endPointA == endPointB) { if (offsetA < offsetB) return 1; if (offsetA == offsetB) return 0; return -1; } // case 2: Child C of container A is ancestor of B // This can be quickly tested by walking the parent chain of B for ( Node c = endPointB, p = c.getParentNode(); p != null; c = p, p = p.getParentNode()) { if (p == endPointA) { int index = indexOf(c, endPointA); if (offsetA <= index) return 1; return -1; } } // case 3: Child C of container B is ancestor of A // This can be quickly tested by walking the parent chain of A for ( Node c = endPointA, p = c.getParentNode(); p != null; c = p, p = p.getParentNode()) { if (p == endPointB) { int index = indexOf(c, endPointB); if (index < offsetB) return 1; return -1; } } // case 4: preorder traversal of context tree. // Instead of literally walking the context tree in pre-order, // we use relative node depth walking which is usually faster int depthDiff = 0; for ( Node n = endPointA; n != null; n = n.getParentNode() ) depthDiff++; for ( Node n = endPointB; n != null; n = n.getParentNode() ) depthDiff--; while (depthDiff > 0) { endPointA = endPointA.getParentNode(); depthDiff--; } while (depthDiff < 0) { endPointB = endPointB.getParentNode(); depthDiff++; } for (Node pA = endPointA.getParentNode(), pB = endPointB.getParentNode(); pA != pB; pA = pA.getParentNode(), pB = pB.getParentNode() ) { endPointA = pA; endPointB = pB; } for ( Node n = endPointA.getNextSibling(); n != null; n = n.getNextSibling() ) { if (n == endPointB) { return 1; } } return -1; } public void deleteContents() throws DOMException { traverseContents(DELETE_CONTENTS); } public DocumentFragment extractContents() throws DOMException { return traverseContents(EXTRACT_CONTENTS); } public DocumentFragment cloneContents() throws DOMException { return traverseContents(CLONE_CONTENTS); } public void insertNode(Node newNode) throws DOMException, RangeException { if ( newNode == null ) return; //throw exception? int type = newNode.getNodeType(); if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if ( fDocument != newNode.getOwnerDocument() ) { throw new DOMException(DOMException.WRONG_DOCUMENT_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "WRONG_DOCUMENT_ERR", null)); } if (type == Node.ATTRIBUTE_NODE || type == Node.ENTITY_NODE || type == Node.NOTATION_NODE || type == Node.DOCUMENT_NODE) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } } Node cloneCurrent; Node current; int currentChildren = 0; fInsertedFromRange = true; //boolean MULTIPLE_MODE = false; if (fStartContainer.getNodeType() == Node.TEXT_NODE) { Node parent = fStartContainer.getParentNode(); currentChildren = parent.getChildNodes().getLength(); //holds number of kids before insertion // split text node: results is 3 nodes.. cloneCurrent = fStartContainer.cloneNode(false); ((TextImpl)cloneCurrent).setNodeValueInternal( (cloneCurrent.getNodeValue()).substring(fStartOffset)); ((TextImpl)fStartContainer).setNodeValueInternal( (fStartContainer.getNodeValue()).substring(0,fStartOffset)); Node next = fStartContainer.getNextSibling(); if (next != null) { if (parent != null) { parent.insertBefore(newNode, next); parent.insertBefore(cloneCurrent, next); } } else { if (parent != null) { parent.appendChild(newNode); parent.appendChild(cloneCurrent); } } //update ranges after the insertion if ( fEndContainer == fStartContainer) { fEndContainer = cloneCurrent; //endContainer is the new Node created fEndOffset -= fStartOffset; } else if ( fEndContainer == parent ) { //endContainer was not a text Node. //endOffset + = number_of_children_added fEndOffset += (parent.getChildNodes().getLength() - currentChildren); } // signal other Ranges to update their start/end containers/offsets signalSplitData(fStartContainer, cloneCurrent, fStartOffset); } else { // ! TEXT_NODE if ( fEndContainer == fStartContainer ) //need to remember number of kids currentChildren= fEndContainer.getChildNodes().getLength(); current = fStartContainer.getFirstChild(); int i = 0; for(i = 0; i < fStartOffset && current != null; i++) { current=current.getNextSibling(); } if (current != null) { fStartContainer.insertBefore(newNode, current); } else { fStartContainer.appendChild(newNode); } //update fEndOffset. ex:

. Range(start;end): body,0; body,1 // insert

:

. Range(start;end): body,0; body,2 if ( fEndContainer == fStartContainer && fEndOffset != 0 ) { //update fEndOffset if not 0 fEndOffset += (fEndContainer.getChildNodes().getLength() - currentChildren); } } fInsertedFromRange = false; } public void surroundContents(Node newParent) throws DOMException, RangeException { if (newParent==null) return; int type = newParent.getNodeType(); if (fDocument.errorChecking) { if (fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } if (type == Node.ATTRIBUTE_NODE || type == Node.ENTITY_NODE || type == Node.NOTATION_NODE || type == Node.DOCUMENT_TYPE_NODE || type == Node.DOCUMENT_NODE || type == Node.DOCUMENT_FRAGMENT_NODE) { throw new RangeExceptionImpl( RangeException.INVALID_NODE_TYPE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_NODE_TYPE_ERR", null)); } } Node realStart = fStartContainer; Node realEnd = fEndContainer; if (fStartContainer.getNodeType() == Node.TEXT_NODE) { realStart = fStartContainer.getParentNode(); } if (fEndContainer.getNodeType() == Node.TEXT_NODE) { realEnd = fEndContainer.getParentNode(); } if (realStart != realEnd) { throw new RangeExceptionImpl( RangeException.BAD_BOUNDARYPOINTS_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "BAD_BOUNDARYPOINTS_ERR", null)); } DocumentFragment frag = extractContents(); insertNode(newParent); newParent.appendChild(frag); selectNode(newParent); } public Range cloneRange(){ if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } Range range = fDocument.createRange(); range.setStart(fStartContainer, fStartOffset); range.setEnd(fEndContainer, fEndOffset); return range; } public String toString(){ if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } Node node = fStartContainer; Node stopNode = fEndContainer; StringBuffer sb = new StringBuffer(); if (fStartContainer.getNodeType() == Node.TEXT_NODE || fStartContainer.getNodeType() == Node.CDATA_SECTION_NODE ) { if (fStartContainer == fEndContainer) { sb.append(fStartContainer.getNodeValue().substring(fStartOffset, fEndOffset)); return sb.toString(); } sb.append(fStartContainer.getNodeValue().substring(fStartOffset)); node=nextNode (node,true); //fEndContainer!=fStartContainer } else { //fStartContainer is not a TextNode node=node.getFirstChild(); if (fStartOffset>0) { //find a first node within a range, specified by fStartOffset int counter=0; while (counter0 && stopNode!=null ){ --i; stopNode = stopNode.getNextSibling(); } if ( stopNode == null ) stopNode = nextNode( fEndContainer, false ); } while (node != stopNode) { //look into all kids of the Range if (node == null) break; if (node.getNodeType() == Node.TEXT_NODE || node.getNodeType() == Node.CDATA_SECTION_NODE) { sb.append(node.getNodeValue()); } node = nextNode(node, true); } if (fEndContainer.getNodeType() == Node.TEXT_NODE || fEndContainer.getNodeType() == Node.CDATA_SECTION_NODE) { sb.append(fEndContainer.getNodeValue().substring(0,fEndOffset)); } return sb.toString(); } public void detach() { if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } fDetach = true; fDocument.removeRange(this); } // // Mutation functions // /** Signal other Ranges to update their start/end * containers/offsets. The data has already been split * into the two Nodes. */ void signalSplitData(Node node, Node newNode, int offset) { fSplitNode = node; // notify document fDocument.splitData(node, newNode, offset); fSplitNode = null; } /** Fix up this Range if another Range has split a Text Node * into 2 Nodes. */ void receiveSplitData(Node node, Node newNode, int offset) { if (node == null || newNode == null) return; if (fSplitNode == node) return; if (node == fStartContainer && fStartContainer.getNodeType() == Node.TEXT_NODE) { if (fStartOffset > offset) { fStartOffset = fStartOffset - offset; fStartContainer = newNode; } } if (node == fEndContainer && fEndContainer.getNodeType() == Node.TEXT_NODE) { if (fEndOffset > offset) { fEndOffset = fEndOffset-offset; fEndContainer = newNode; } } } /** This function inserts text into a Node and invokes * a method to fix-up all other Ranges. */ void deleteData(CharacterData node, int offset, int count) { fDeleteNode = node; node.deleteData( offset, count); fDeleteNode = null; } /** This function is called from DOM. * The text has already beeen inserted. * Fix-up any offsets. */ void receiveDeletedText(Node node, int offset, int count) { if (node == null) return; if (fDeleteNode == node) return; if (node == fStartContainer && fStartContainer.getNodeType() == Node.TEXT_NODE) { if (fStartOffset > offset+count) { fStartOffset = offset+(fStartOffset-(offset+count)); } else if (fStartOffset > offset) { fStartOffset = offset; } } if (node == fEndContainer && fEndContainer.getNodeType() == Node.TEXT_NODE) { if (fEndOffset > offset+count) { fEndOffset = offset+(fEndOffset-(offset+count)); } else if (fEndOffset > offset) { fEndOffset = offset; } } } /** This function inserts text into a Node and invokes * a method to fix-up all other Ranges. */ void insertData(CharacterData node, int index, String insert) { fInsertNode = node; node.insertData( index, insert); fInsertNode = null; } /** This function is called from DOM. * The text has already beeen inserted. * Fix-up any offsets. */ void receiveInsertedText(Node node, int index, int len) { if (node == null) return; if (fInsertNode == node) return; if (node == fStartContainer && fStartContainer.getNodeType() == Node.TEXT_NODE) { if (index < fStartOffset) { fStartOffset = fStartOffset+len; } } if (node == fEndContainer && fEndContainer.getNodeType() == Node.TEXT_NODE) { if (index < fEndOffset) { fEndOffset = fEndOffset+len; } } } /** This function is called from DOM. * The text has already beeen replaced. * Fix-up any offsets. */ void receiveReplacedText(Node node) { if (node == null) return; if (node == fStartContainer && fStartContainer.getNodeType() == Node.TEXT_NODE) { fStartOffset = 0; } if (node == fEndContainer && fEndContainer.getNodeType() == Node.TEXT_NODE) { fEndOffset = 0; } } /** This function is called from the DOM. * This node has already been inserted into the DOM. * Fix-up any offsets. */ public void insertedNodeFromDOM(Node node) { if (node == null) return; if (fInsertNode == node) return; if (fInsertedFromRange) return; // Offsets are adjusted in Range.insertNode Node parent = node.getParentNode(); if (parent == fStartContainer) { int index = indexOf(node, fStartContainer); if (index < fStartOffset) { fStartOffset++; } } if (parent == fEndContainer) { int index = indexOf(node, fEndContainer); if (index < fEndOffset) { fEndOffset++; } } } /** This function is called within Range * instead of Node.removeChild, * so that the range can remember that it is actively * removing this child. */ Node fRemoveChild = null; Node removeChild(Node parent, Node child) { fRemoveChild = child; Node n = parent.removeChild(child); fRemoveChild = null; return n; } /** This function must be called by the DOM _BEFORE_ * a node is deleted, because at that time it is * connected in the DOM tree, which we depend on. */ void removeNode(Node node) { if (node == null) return; if (fRemoveChild == node) return; Node parent = node.getParentNode(); if (parent == fStartContainer) { int index = indexOf(node, fStartContainer); if (index < fStartOffset) { fStartOffset--; } } if (parent == fEndContainer) { int index = indexOf(node, fEndContainer); if (index < fEndOffset) { fEndOffset--; } } //startContainer or endContainer or both is/are the ancestor(s) of the Node to be deleted if (parent != fStartContainer || parent != fEndContainer) { if (isAncestorOf(node, fStartContainer)) { fStartContainer = parent; fStartOffset = indexOf( node, parent); } if (isAncestorOf(node, fEndContainer)) { fEndContainer = parent; fEndOffset = indexOf( node, parent); } } } // // Utility functions. // // parameters for traverseContents(int) //REVIST: use boolean, since there are only 2 now... static final int EXTRACT_CONTENTS = 1; static final int CLONE_CONTENTS = 2; static final int DELETE_CONTENTS = 3; /** * This is the master routine invoked to visit the nodes * selected by this range. For each such node, different * actions are taken depending on the value of the * how argument. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *

    *
  1. EXTRACT_CONTENTS - will produce * a document fragment containing the range's content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but sill * produced cloned content in a document fragment * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes. *
* * @return Returns a document fragment containing any * copied or extracted nodes. If the how * parameter was DELETE_CONTENTS, the * return value is null. */ private DocumentFragment traverseContents( int how ) throws DOMException { if (fStartContainer == null || fEndContainer == null) { return null; // REVIST: Throw exception? } //Check for a detached range. if( fDetach) { throw new DOMException( DOMException.INVALID_STATE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INVALID_STATE_ERR", null)); } /* Traversal is accomplished by first determining the relationship between the endpoints of the range. For each of four significant relationships, we will delegate the traversal call to a method that can make appropriate assumptions. */ // case 1: same container if ( fStartContainer == fEndContainer ) return traverseSameContainer( how ); // case 2: Child C of start container is ancestor of end container // This can be quickly tested by walking the parent chain of // end container int endContainerDepth = 0; for ( Node c = fEndContainer, p = c.getParentNode(); p != null; c = p, p = p.getParentNode()) { if (p == fStartContainer) return traverseCommonStartContainer( c, how ); ++endContainerDepth; } // case 3: Child C of container B is ancestor of A // This can be quickly tested by walking the parent chain of A int startContainerDepth = 0; for ( Node c = fStartContainer, p = c.getParentNode(); p != null; c = p, p = p.getParentNode()) { if (p == fEndContainer) return traverseCommonEndContainer( c, how ); ++startContainerDepth; } // case 4: There is a common ancestor container. Find the // ancestor siblings that are children of that container. int depthDiff = startContainerDepth - endContainerDepth; Node startNode = fStartContainer; while (depthDiff > 0) { startNode = startNode.getParentNode(); depthDiff--; } Node endNode = fEndContainer; while (depthDiff < 0) { endNode = endNode.getParentNode(); depthDiff++; } // ascend the ancestor hierarchy until we have a common parent. for( Node sp = startNode.getParentNode(), ep = endNode.getParentNode(); sp!=ep; sp = sp.getParentNode(), ep = ep.getParentNode() ) { startNode = sp; endNode = ep; } return traverseCommonAncestors( startNode, endNode, how ); } /** * Visits the nodes selected by this range when we know * a-priori that the start and end containers are the same. * This method is invoked by the generic traverse * method. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will produce * a document fragment containing the range's content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but sill * produced cloned content in a document fragment * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes. *
* * @return Returns a document fragment containing any * copied or extracted nodes. If the how * parameter was DELETE_CONTENTS, the * return value is null. */ private DocumentFragment traverseSameContainer( int how ) { DocumentFragment frag = null; if ( how!=DELETE_CONTENTS) frag = fDocument.createDocumentFragment(); // If selection is empty, just return the fragment if ( fStartOffset==fEndOffset ) return frag; // Text node needs special case handling if ( fStartContainer.getNodeType()==Node.TEXT_NODE ) { // get the substring String s = fStartContainer.getNodeValue(); String sub = s.substring( fStartOffset, fEndOffset ); // set the original text node to its new value if ( how != CLONE_CONTENTS ) { ((TextImpl)fStartContainer).deleteData(fStartOffset, fEndOffset-fStartOffset) ; // Nothing is partially selected, so collapse to start point collapse( true ); } if ( how==DELETE_CONTENTS) return null; frag.appendChild( fDocument.createTextNode(sub) ); return frag; } // Copy nodes between the start/end offsets. Node n = getSelectedNode( fStartContainer, fStartOffset ); int cnt = fEndOffset - fStartOffset; while( cnt > 0 ) { Node sibling = n.getNextSibling(); Node xferNode = traverseFullySelected( n, how ); if ( frag!=null ) frag.appendChild( xferNode ); --cnt; n = sibling; } // Nothing is partially selected, so collapse to start point if ( how != CLONE_CONTENTS ) collapse( true ); return frag; } /** * Visits the nodes selected by this range when we know * a-priori that the start and end containers are not the * same, but the start container is an ancestor of the * end container. This method is invoked by the generic * traverse method. * * @param endAncestor * The ancestor of the end container that is a direct child * of the start container. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will produce * a document fragment containing the range's content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but sill * produced cloned content in a document fragment * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes. *
* * @return Returns a document fragment containing any * copied or extracted nodes. If the how * parameter was DELETE_CONTENTS, the * return value is null. */ private DocumentFragment traverseCommonStartContainer( Node endAncestor, int how ) { DocumentFragment frag = null; if ( how!=DELETE_CONTENTS) frag = fDocument.createDocumentFragment(); Node n = traverseRightBoundary( endAncestor, how ); if ( frag!=null ) frag.appendChild( n ); int endIdx = indexOf( endAncestor, fStartContainer ); int cnt = endIdx - fStartOffset; if ( cnt <=0 ) { // Collapse to just before the endAncestor, which // is partially selected. if ( how != CLONE_CONTENTS ) { setEndBefore( endAncestor ); collapse( false ); } return frag; } n = endAncestor.getPreviousSibling(); while( cnt > 0 ) { Node sibling = n.getPreviousSibling(); Node xferNode = traverseFullySelected( n, how ); if ( frag!=null ) frag.insertBefore( xferNode, frag.getFirstChild() ); --cnt; n = sibling; } // Collapse to just before the endAncestor, which // is partially selected. if ( how != CLONE_CONTENTS ) { setEndBefore( endAncestor ); collapse( false ); } return frag; } /** * Visits the nodes selected by this range when we know * a-priori that the start and end containers are not the * same, but the end container is an ancestor of the * start container. This method is invoked by the generic * traverse method. * * @param startAncestor * The ancestor of the start container that is a direct * child of the end container. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will produce * a document fragment containing the range's content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but sill * produced cloned content in a document fragment * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes. *
* * @return Returns a document fragment containing any * copied or extracted nodes. If the how * parameter was DELETE_CONTENTS, the * return value is null. */ private DocumentFragment traverseCommonEndContainer( Node startAncestor, int how ) { DocumentFragment frag = null; if ( how!=DELETE_CONTENTS) frag = fDocument.createDocumentFragment(); Node n = traverseLeftBoundary( startAncestor, how ); if ( frag!=null ) frag.appendChild( n ); int startIdx = indexOf( startAncestor, fEndContainer ); ++startIdx; // Because we already traversed it.... int cnt = fEndOffset - startIdx; n = startAncestor.getNextSibling(); while( cnt > 0 ) { Node sibling = n.getNextSibling(); Node xferNode = traverseFullySelected( n, how ); if ( frag!=null ) frag.appendChild( xferNode ); --cnt; n = sibling; } if ( how != CLONE_CONTENTS ) { setStartAfter( startAncestor ); collapse( true ); } return frag; } /** * Visits the nodes selected by this range when we know * a-priori that the start and end containers are not * the same, and we also know that neither the start * nor end container is an ancestor of the other. * This method is invoked by * the generic traverse method. * * @param startAncestor * Given a common ancestor of the start and end containers, * this parameter is the ancestor (or self) of the start * container that is a direct child of the common ancestor. * * @param endAncestor * Given a common ancestor of the start and end containers, * this parameter is the ancestor (or self) of the end * container that is a direct child of the common ancestor. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will produce * a document fragment containing the range's content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but sill * produced cloned content in a document fragment * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes. *
* * @return Returns a document fragment containing any * copied or extracted nodes. If the how * parameter was DELETE_CONTENTS, the * return value is null. */ private DocumentFragment traverseCommonAncestors( Node startAncestor, Node endAncestor, int how ) { DocumentFragment frag = null; if ( how!=DELETE_CONTENTS) frag = fDocument.createDocumentFragment(); Node n = traverseLeftBoundary( startAncestor, how ); if ( frag!=null ) frag.appendChild( n ); Node commonParent = startAncestor.getParentNode(); int startOffset = indexOf( startAncestor, commonParent ); int endOffset = indexOf( endAncestor, commonParent ); ++startOffset; int cnt = endOffset - startOffset; Node sibling = startAncestor.getNextSibling(); while( cnt > 0 ) { Node nextSibling = sibling.getNextSibling(); n = traverseFullySelected( sibling, how ); if ( frag!=null ) frag.appendChild( n ); sibling = nextSibling; --cnt; } n = traverseRightBoundary( endAncestor, how ); if ( frag!=null ) frag.appendChild( n ); if ( how != CLONE_CONTENTS ) { setStartAfter( startAncestor ); collapse( true ); } return frag; } /** * Traverses the "right boundary" of this range and * operates on each "boundary node" according to the * how parameter. It is a-priori assumed * by this method that the right boundary does * not contain the range's start container. *

* A "right boundary" is best visualized by thinking * of a sample tree:

     *                 A
     *                /|\
     *               / | \
     *              /  |  \
     *             B   C   D
     *            /|\     /|\
     *           E F G   H I J
     * 
* Imagine first a range that begins between the * "E" and "F" nodes and ends between the * "I" and "J" nodes. The start container is * "B" and the end container is "D". Given this setup, * the following applies: *

* Partially Selected Nodes: B, D
* Fully Selected Nodes: F, G, C, H, I *

* The "right boundary" is the highest subtree node * that contains the ending container. The root of * this subtree is always partially selected. *

* In this example, the nodes that are traversed * as "right boundary" nodes are: H, I, and D. * * @param root The node that is the root of the "right boundary" subtree. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *

    *
  1. EXTRACT_CONTENTS - will produce * a node containing the boundaries content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * produced cloned content. * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes within the boundary. *
* * @return Returns a node that is the result of visiting nodes. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traverseRightBoundary( Node root, int how ) { Node next = getSelectedNode( fEndContainer, fEndOffset-1 ); boolean isFullySelected = ( next!=fEndContainer ); if ( next==root ) return traverseNode( next, isFullySelected, false, how ); Node parent = next.getParentNode(); Node clonedParent = traverseNode( parent, false, false, how ); while( parent!=null ) { while( next!=null ) { Node prevSibling = next.getPreviousSibling(); Node clonedChild = traverseNode( next, isFullySelected, false, how ); if ( how!=DELETE_CONTENTS ) { clonedParent.insertBefore( clonedChild, clonedParent.getFirstChild() ); } isFullySelected = true; next = prevSibling; } if ( parent==root ) return clonedParent; next = parent.getPreviousSibling(); parent = parent.getParentNode(); Node clonedGrandParent = traverseNode( parent, false, false, how ); if ( how!=DELETE_CONTENTS ) clonedGrandParent.appendChild( clonedParent ); clonedParent = clonedGrandParent; } // should never occur return null; } /** * Traverses the "left boundary" of this range and * operates on each "boundary node" according to the * how parameter. It is a-priori assumed * by this method that the left boundary does * not contain the range's end container. *

* A "left boundary" is best visualized by thinking * of a sample tree:

     *
     *                 A
     *                /|\
     *               / | \
     *              /  |  \
     *             B   C   D
     *            /|\     /|\
     *           E F G   H I J
     * 
* Imagine first a range that begins between the * "E" and "F" nodes and ends between the * "I" and "J" nodes. The start container is * "B" and the end container is "D". Given this setup, * the following applies: *

* Partially Selected Nodes: B, D
* Fully Selected Nodes: F, G, C, H, I *

* The "left boundary" is the highest subtree node * that contains the starting container. The root of * this subtree is always partially selected. *

* In this example, the nodes that are traversed * as "left boundary" nodes are: F, G, and B. * * @param root The node that is the root of the "left boundary" subtree. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *

    *
  1. EXTRACT_CONTENTS - will produce * a node containing the boundaries content. * Partially selected nodes are copied, but fully * selected nodes are moved. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * produced cloned content. * *
  3. DELETE_CONTENTS - will delete from * the context tree of the range, all fully selected * nodes within the boundary. *
* * @return Returns a node that is the result of visiting nodes. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traverseLeftBoundary( Node root, int how ) { Node next = getSelectedNode( getStartContainer(), getStartOffset() ); boolean isFullySelected = ( next!=getStartContainer() ); if ( next==root ) return traverseNode( next, isFullySelected, true, how ); Node parent = next.getParentNode(); Node clonedParent = traverseNode( parent, false, true, how ); while( parent!=null ) { while( next!=null ) { Node nextSibling = next.getNextSibling(); Node clonedChild = traverseNode( next, isFullySelected, true, how ); if ( how!=DELETE_CONTENTS ) clonedParent.appendChild(clonedChild); isFullySelected = true; next = nextSibling; } if ( parent==root ) return clonedParent; next = parent.getNextSibling(); parent = parent.getParentNode(); Node clonedGrandParent = traverseNode( parent, false, true, how ); if ( how!=DELETE_CONTENTS ) clonedGrandParent.appendChild( clonedParent ); clonedParent = clonedGrandParent; } // should never occur return null; } /** * Utility method for traversing a single node. * Does not properly handle a text node containing both the * start and end offsets. Such nodes should * have been previously detected and been routed to traverseTextNode. * * @param n The node to be traversed. * * @param isFullySelected * Set to true if the node is fully selected. Should be * false otherwise. * Note that although the DOM 2 specification says that a * text node that is boththe start and end container is not * selected, we treat it here as if it were partially * selected. * * @param isLeft Is true if we are traversing the node as part of navigating * the "left boundary" of the range. If this value is false, * it implies we are navigating the "right boundary" of the * range. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will simply * return the original node. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * return a cloned node. * *
  3. DELETE_CONTENTS - will delete the * node from it's parent, but will return null. *
* * @return Returns a node that is the result of visiting the node. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traverseNode( Node n, boolean isFullySelected, boolean isLeft, int how ) { if ( isFullySelected ) return traverseFullySelected( n, how ); if ( n.getNodeType()==Node.TEXT_NODE ) return traverseTextNode( n, isLeft, how ); return traversePartiallySelected( n, how ); } /** * Utility method for traversing a single node when * we know a-priori that the node if fully * selected. * * @param n The node to be traversed. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will simply * return the original node. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * return a cloned node. * *
  3. DELETE_CONTENTS - will delete the * node from it's parent, but will return null. *
* * @return Returns a node that is the result of visiting the node. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traverseFullySelected( Node n, int how ) { switch( how ) { case CLONE_CONTENTS: return n.cloneNode( true ); case EXTRACT_CONTENTS: if ( n.getNodeType()==Node.DOCUMENT_TYPE_NODE ) { // TBD: This should be a HIERARCHY_REQUEST_ERR throw new DOMException( DOMException.HIERARCHY_REQUEST_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "HIERARCHY_REQUEST_ERR", null)); } return n; case DELETE_CONTENTS: n.getParentNode().removeChild(n); return null; } return null; } /** * Utility method for traversing a single node when * we know a-priori that the node if partially * selected and is not a text node. * * @param n The node to be traversed. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will simply * return the original node. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * return a cloned node. * *
  3. DELETE_CONTENTS - will delete the * node from it's parent, but will return null. *
* * @return Returns a node that is the result of visiting the node. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traversePartiallySelected( Node n, int how ) { switch( how ) { case DELETE_CONTENTS: return null; case CLONE_CONTENTS: case EXTRACT_CONTENTS: return n.cloneNode( false ); } return null; } /** * Utility method for traversing a text node that we know * a-priori to be on a left or right boundary of the range. * This method does not properly handle text nodes that contain * both the start and end points of the range. * * @param n The node to be traversed. * * @param isLeft Is true if we are traversing the node as part of navigating * the "left boundary" of the range. If this value is false, * it implies we are navigating the "right boundary" of the * range. * * @param how Specifies what type of traversal is being * requested (extract, clone, or delete). * Legal values for this argument are: * *
    *
  1. EXTRACT_CONTENTS - will simply * return the original node. * *
  2. CLONE_CONTENTS - will leave the * context tree of the range undisturbed, but will * return a cloned node. * *
  3. DELETE_CONTENTS - will delete the * node from it's parent, but will return null. *
* * @return Returns a node that is the result of visiting the node. * If the traversal operation is * DELETE_CONTENTS the return value is null. */ private Node traverseTextNode( Node n, boolean isLeft, int how ) { String txtValue = n.getNodeValue(); String newNodeValue; String oldNodeValue; if ( isLeft ) { int offset = getStartOffset(); newNodeValue = txtValue.substring( offset ); oldNodeValue = txtValue.substring( 0, offset ); } else { int offset = getEndOffset(); newNodeValue = txtValue.substring( 0, offset ); oldNodeValue = txtValue.substring( offset ); } if ( how != CLONE_CONTENTS ) n.setNodeValue( oldNodeValue ); if ( how==DELETE_CONTENTS ) return null; Node newNode = n.cloneNode( false ); newNode.setNodeValue( newNodeValue ); return newNode; } void checkIndex(Node refNode, int offset) throws DOMException { if (offset < 0) { throw new DOMException( DOMException.INDEX_SIZE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INDEX_SIZE_ERR", null)); } int type = refNode.getNodeType(); // If the node contains text, ensure that the // offset of the range is <= to the length of the text if (type == Node.TEXT_NODE || type == Node.CDATA_SECTION_NODE || type == Node.COMMENT_NODE || type == Node.PROCESSING_INSTRUCTION_NODE) { if (offset > refNode.getNodeValue().length()) { throw new DOMException(DOMException.INDEX_SIZE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INDEX_SIZE_ERR", null)); } } else { // Since the node is not text, ensure that the offset // is valid with respect to the number of child nodes if (offset > refNode.getChildNodes().getLength()) { throw new DOMException(DOMException.INDEX_SIZE_ERR, DOMMessageFormatter.formatMessage(DOMMessageFormatter.DOM_DOMAIN, "INDEX_SIZE_ERR", null)); } } } /** * Given a node, calculate what the Range's root container * for that node would be. */ private Node getRootContainer( Node node ) { if ( node==null ) return null; while( node.getParentNode()!=null ) node = node.getParentNode(); return node; } /** * Returns true IFF the given node can serve as a container * for a range's boundary points. */ private boolean isLegalContainer( Node node ) { if ( node==null ) return false; while( node!=null ) { switch( node.getNodeType() ) { case Node.ENTITY_NODE: case Node.NOTATION_NODE: case Node.DOCUMENT_TYPE_NODE: return false; } node = node.getParentNode(); } return true; } /** * Finds the root container for the given node and determines * if that root container is legal with respect to the * DOM 2 specification. At present, that means the root * container must be either an attribute, a document, * or a document fragment. */ private boolean hasLegalRootContainer( Node node ) { if ( node==null ) return false; Node rootContainer = getRootContainer( node ); switch( rootContainer.getNodeType() ) { case Node.ATTRIBUTE_NODE: case Node.DOCUMENT_NODE: case Node.DOCUMENT_FRAGMENT_NODE: return true; } return false; } /** * Returns true IFF the given node can be contained by * a range. */ private boolean isLegalContainedNode( Node node ) { if ( node==null ) return false; switch( node.getNodeType() ) { case Node.DOCUMENT_NODE: case Node.DOCUMENT_FRAGMENT_NODE: case Node.ATTRIBUTE_NODE: case Node.ENTITY_NODE: case Node.NOTATION_NODE: return false; } return true; } Node nextNode(Node node, boolean visitChildren) { if (node == null) return null; Node result; if (visitChildren) { result = node.getFirstChild(); if (result != null) { return result; } } // if hasSibling, return sibling result = node.getNextSibling(); if (result != null) { return result; } // return parent's 1st sibling. Node parent = node.getParentNode(); while (parent != null && parent != fDocument ) { result = parent.getNextSibling(); if (result != null) { return result; } else { parent = parent.getParentNode(); } } // while (parent != null && parent != fRoot) { // end of list, return null return null; } /** is a an ancestor of b ? */ boolean isAncestorOf(Node a, Node b) { for (Node node=b; node != null; node=node.getParentNode()) { if (node == a) return true; } return false; } /** what is the index of the child in the parent */ int indexOf(Node child, Node parent) { if (child.getParentNode() != parent) return -1; int i = 0; for(Node node = parent.getFirstChild(); node!= child; node=node.getNextSibling()) { i++; } return i; } /** * Utility method to retrieve a child node by index. This method * assumes the caller is trying to find out which node is * selected by the given index. Note that if the index is * greater than the number of children, this implies that the * first node selected is the parent node itself. * * @param container A container node * * @param offset An offset within the container for which a selected node should * be computed. If the offset is less than zero, or if the offset * is greater than the number of children, the container is returned. * * @return Returns either a child node of the container or the * container itself. */ private Node getSelectedNode( Node container, int offset ) { if ( container.getNodeType() == Node.TEXT_NODE ) return container; // This case is an important convenience for // traverseRightBoundary() if ( offset<0 ) return container; Node child = container.getFirstChild(); while( child!=null && offset > 0 ) { --offset; child = child.getNextSibling(); } if ( child!=null ) return child; return container; } }




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