/* * Copyright 1999-2004 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 * * Unless required by applicable law or agreed to in writing, software * distributed under the License is distributed on an "AS IS" BASIS, * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. * See the License for the specific language governing permissions and * limitations under the License. */ /* * $Id: MatchPatternIterator.java,v 1.8 2004/02/17 04:32:08 minchau Exp $ */ package com.sun.org.apache.xpath.internal.axes; import com.sun.org.apache.xml.internal.dtm.Axis; import com.sun.org.apache.xml.internal.dtm.DTM; import com.sun.org.apache.xml.internal.dtm.DTMAxisTraverser; import com.sun.org.apache.xml.internal.dtm.DTMIterator; import com.sun.org.apache.xpath.internal.XPathContext; import com.sun.org.apache.xpath.internal.compiler.Compiler; import com.sun.org.apache.xpath.internal.objects.XObject; import com.sun.org.apache.xpath.internal.patterns.NodeTest; import com.sun.org.apache.xpath.internal.patterns.StepPattern; /** * This class treats a * LocationPath as a * filtered iteration over the tree, evaluating each node in a super axis * traversal against the LocationPath interpreted as a match pattern. This * class is useful to find nodes in document order that are complex paths * whose steps probably criss-cross each other. */ public class MatchPatternIterator extends LocPathIterator { /** This is the select pattern, translated into a match pattern. */ protected StepPattern m_pattern; /** The traversal axis from where the nodes will be filtered. */ protected int m_superAxis = -1; /** The DTM inner traversal class, that corresponds to the super axis. */ protected DTMAxisTraverser m_traverser; /** DEBUG flag for diagnostic dumps. */ private static final boolean DEBUG = false; // protected int m_nsElemBase = DTM.NULL; /** * Create a LocPathIterator object, including creation * of step walkers from the opcode list, and call back * into the Compiler to create predicate expressions. * * @param compiler The Compiler which is creating * this expression. * @param opPos The position of this iterator in the * opcode list from the compiler. * @param analysis Analysis bits that give general information about the * LocationPath. * * @throws javax.xml.transform.TransformerException */ MatchPatternIterator(Compiler compiler, int opPos, int analysis) throws javax.xml.transform.TransformerException { super(compiler, opPos, analysis, false); int firstStepPos = compiler.getFirstChildPos(opPos); m_pattern = WalkerFactory.loadSteps(this, compiler, firstStepPos, 0); boolean fromRoot = false; boolean walkBack = false; boolean walkDescendants = false; boolean walkAttributes = false; if (0 != (analysis & (WalkerFactory.BIT_ROOT | WalkerFactory.BIT_ANY_DESCENDANT_FROM_ROOT))) fromRoot = true; if (0 != (analysis & (WalkerFactory.BIT_ANCESTOR | WalkerFactory.BIT_ANCESTOR_OR_SELF | WalkerFactory.BIT_PRECEDING | WalkerFactory.BIT_PRECEDING_SIBLING | WalkerFactory.BIT_FOLLOWING | WalkerFactory.BIT_FOLLOWING_SIBLING | WalkerFactory.BIT_PARENT | WalkerFactory.BIT_FILTER))) walkBack = true; if (0 != (analysis & (WalkerFactory.BIT_DESCENDANT_OR_SELF | WalkerFactory.BIT_DESCENDANT | WalkerFactory.BIT_CHILD))) walkDescendants = true; if (0 != (analysis & (WalkerFactory.BIT_ATTRIBUTE | WalkerFactory.BIT_NAMESPACE))) walkAttributes = true; if(false || DEBUG) { System.out.print("analysis: "+Integer.toBinaryString(analysis)); System.out.println(", "+WalkerFactory.getAnalysisString(analysis)); } if(fromRoot || walkBack) { if(walkAttributes) { m_superAxis = Axis.ALL; } else { m_superAxis = Axis.DESCENDANTSFROMROOT; } } else if(walkDescendants) { if(walkAttributes) { m_superAxis = Axis.ALLFROMNODE; } else { m_superAxis = Axis.DESCENDANTORSELF; } } else { m_superAxis = Axis.ALL; } if(false || DEBUG) { System.out.println("axis: "+Axis.names[m_superAxis]); } } /** * Initialize the context values for this expression * after it is cloned. * * @param execContext The XPath runtime context for this * transformation. */ public void setRoot(int context, Object environment) { super.setRoot(context, environment); m_traverser = m_cdtm.getAxisTraverser(m_superAxis); } /** * Detaches the iterator from the set which it iterated over, releasing * any computational resources and placing the iterator in the INVALID * state. Afterdetach has been invoked, calls to * nextNode orpreviousNode will raise the * exception INVALID_STATE_ERR. */ public void detach() { if(m_allowDetach) { m_traverser = null; // Always call the superclass detach last! super.detach(); } } /** * Get the next node via getNextXXX. Bottlenecked for derived class override. * @return The next node on the axis, or DTM.NULL. */ protected int getNextNode() { m_lastFetched = (DTM.NULL == m_lastFetched) ? m_traverser.first(m_context) : m_traverser.next(m_context, m_lastFetched); return m_lastFetched; } /** * Returns the next node in the set and advances the position of the * iterator in the set. After a NodeIterator is created, the first call * to nextNode() returns the first node in the set. * @return The next Node in the set being iterated over, or * null if there are no more members in that set. */ public int nextNode() { if(m_foundLast) return DTM.NULL; int next; com.sun.org.apache.xpath.internal.VariableStack vars; int savedStart; if (-1 != m_stackFrame) { vars = m_execContext.getVarStack(); // These three statements need to be combined into one operation. savedStart = vars.getStackFrame(); vars.setStackFrame(m_stackFrame); } else { // Yuck. Just to shut up the compiler! vars = null; savedStart = 0; } try { if(DEBUG) System.out.println("m_pattern"+m_pattern.toString()); do { next = getNextNode(); if (DTM.NULL != next) { if(DTMIterator.FILTER_ACCEPT == acceptNode(next, m_execContext)) break; else continue; } else break; } while (next != DTM.NULL); if (DTM.NULL != next) { if(DEBUG) { System.out.println("next: "+next); System.out.println("name: "+m_cdtm.getNodeName(next)); } incrementCurrentPos(); return next; } else { m_foundLast = true; return DTM.NULL; } } finally { if (-1 != m_stackFrame) { // These two statements need to be combined into one operation. vars.setStackFrame(savedStart); } } } /** * Test whether a specified node is visible in the logical view of a * TreeWalker or NodeIterator. This function will be called by the * implementation of TreeWalker and NodeIterator; it is not intended to * be called directly from user code. * @param n The node to check to see if it passes the filter or not. * @return a constant to determine whether the node is accepted, * rejected, or skipped, as defined above . */ public short acceptNode(int n, XPathContext xctxt) { try { xctxt.pushCurrentNode(n); xctxt.pushIteratorRoot(m_context); if(DEBUG) { System.out.println("traverser: "+m_traverser); System.out.print("node: "+n); System.out.println(", "+m_cdtm.getNodeName(n)); // if(m_cdtm.getNodeName(n).equals("near-east")) System.out.println("pattern: "+m_pattern.toString()); m_pattern.debugWhatToShow(m_pattern.getWhatToShow()); } XObject score = m_pattern.execute(xctxt); if(DEBUG) { // System.out.println("analysis: "+Integer.toBinaryString(m_analysis)); System.out.println("score: "+score); System.out.println("skip: "+(score == NodeTest.SCORE_NONE)); } // System.out.println("\n::acceptNode - score: "+score.num()+"::"); return (score == NodeTest.SCORE_NONE) ? DTMIterator.FILTER_SKIP : DTMIterator.FILTER_ACCEPT; } catch (javax.xml.transform.TransformerException se) { // TODO: Fix this. throw new RuntimeException(se.getMessage()); } finally { xctxt.popCurrentNode(); xctxt.popIteratorRoot(); } } }