/*
* Licensed to the Apache Software Foundation (ASF) under one
* or more contributor license agreements. See the NOTICE file
* distributed with this work for additional information
* regarding copyright ownership. The ASF licenses this file
* to you 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: WalkerFactory.java 469314 2006-10-30 23:31:59Z minchau $
*/
package org.apache.xpath.axes;
import org.apache.xalan.res.XSLMessages;
import org.apache.xml.dtm.Axis;
import org.apache.xml.dtm.DTMFilter;
import org.apache.xml.dtm.DTMIterator;
import org.apache.xpath.Expression;
import org.apache.xpath.compiler.Compiler;
import org.apache.xpath.compiler.FunctionTable;
import org.apache.xpath.compiler.OpCodes;
import org.apache.xpath.compiler.OpMap;
import org.apache.xpath.objects.XNumber;
import org.apache.xpath.patterns.ContextMatchStepPattern;
import org.apache.xpath.patterns.FunctionPattern;
import org.apache.xpath.patterns.NodeTest;
import org.apache.xpath.patterns.StepPattern;
import org.apache.xpath.res.XPATHErrorResources;
This class is both a factory for XPath location path expressions,
which are built from the opcode map output, and an analysis engine
for the location path expressions in order to provide optimization hints.
/**
* This class is both a factory for XPath location path expressions,
* which are built from the opcode map output, and an analysis engine
* for the location path expressions in order to provide optimization hints.
*/
public class WalkerFactory
{
This method is for building an array of possible levels
where the target element(s) could be found for a match.
Params: - lpi – The owning location path iterator.
- compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
Throws: Returns: non-null AxesWalker derivative. @xsl.usage advanced
/**
* This method is for building an array of possible levels
* where the target element(s) could be found for a match.
* @param lpi The owning location path iterator.
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
*
* @return non-null AxesWalker derivative.
*
* @throws javax.xml.transform.TransformerException
* @xsl.usage advanced
*/
static AxesWalker loadOneWalker(
WalkingIterator lpi, Compiler compiler, int stepOpCodePos)
throws javax.xml.transform.TransformerException
{
AxesWalker firstWalker = null;
int stepType = compiler.getOp(stepOpCodePos);
if (stepType != OpCodes.ENDOP)
{
// m_axesWalkers = new AxesWalker[1];
// As we unwind from the recursion, create the iterators.
firstWalker = createDefaultWalker(compiler, stepType, lpi, 0);
firstWalker.init(compiler, stepOpCodePos, stepType);
}
return firstWalker;
}
This method is for building an array of possible levels
where the target element(s) could be found for a match.
Params: - lpi – The owning location path iterator object.
- compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
- stepIndex – The top-level step index withing the iterator.
Throws: Returns: non-null AxesWalker derivative. @xsl.usage advanced
/**
* This method is for building an array of possible levels
* where the target element(s) could be found for a match.
* @param lpi The owning location path iterator object.
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
* @param stepIndex The top-level step index withing the iterator.
*
* @return non-null AxesWalker derivative.
*
* @throws javax.xml.transform.TransformerException
* @xsl.usage advanced
*/
static AxesWalker loadWalkers(
WalkingIterator lpi, Compiler compiler, int stepOpCodePos, int stepIndex)
throws javax.xml.transform.TransformerException
{
int stepType;
AxesWalker firstWalker = null;
AxesWalker walker, prevWalker = null;
int analysis = analyze(compiler, stepOpCodePos, stepIndex);
while (OpCodes.ENDOP != (stepType = compiler.getOp(stepOpCodePos)))
{
walker = createDefaultWalker(compiler, stepOpCodePos, lpi, analysis);
walker.init(compiler, stepOpCodePos, stepType);
walker.exprSetParent(lpi);
// walker.setAnalysis(analysis);
if (null == firstWalker)
{
firstWalker = walker;
}
else
{
prevWalker.setNextWalker(walker);
walker.setPrevWalker(prevWalker);
}
prevWalker = walker;
stepOpCodePos = compiler.getNextStepPos(stepOpCodePos);
if (stepOpCodePos < 0)
break;
}
return firstWalker;
}
public static boolean isSet(int analysis, int bits)
{
return (0 != (analysis & bits));
}
public static void diagnoseIterator(String name, int analysis, Compiler compiler)
{
System.out.println(compiler.toString()+", "+name+", "
+ Integer.toBinaryString(analysis) + ", "
+ getAnalysisString(analysis));
}
Create a new LocPathIterator iterator. The exact type of iterator
returned is based on an analysis of the XPath operations.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- opPos – The position of the operation code for this itterator.
Throws: Returns: non-null reference to a LocPathIterator or derivative.
/**
* Create a new LocPathIterator iterator. The exact type of iterator
* returned is based on an analysis of the XPath operations.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param opPos The position of the operation code for this itterator.
*
* @return non-null reference to a LocPathIterator or derivative.
*
* @throws javax.xml.transform.TransformerException
*/
public static DTMIterator newDTMIterator(
Compiler compiler, int opPos,
boolean isTopLevel)
throws javax.xml.transform.TransformerException
{
int firstStepPos = OpMap.getFirstChildPos(opPos);
int analysis = analyze(compiler, firstStepPos, 0);
boolean isOneStep = isOneStep(analysis);
DTMIterator iter;
// Is the iteration a one-step attribute pattern (i.e. select="@foo")?
if (isOneStep && walksSelfOnly(analysis) &&
isWild(analysis) && !hasPredicate(analysis))
{
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("SelfIteratorNoPredicate", analysis, compiler);
// Then use a simple iteration of the attributes, with node test
// and predicate testing.
iter = new SelfIteratorNoPredicate(compiler, opPos, analysis);
}
// Is the iteration exactly one child step?
else if (walksChildrenOnly(analysis) && isOneStep)
{
// Does the pattern specify *any* child with no predicate? (i.e. select="child::node()".
if (isWild(analysis) && !hasPredicate(analysis))
{
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("ChildIterator", analysis, compiler);
// Use simple child iteration without any test.
iter = new ChildIterator(compiler, opPos, analysis);
}
else
{
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("ChildTestIterator", analysis, compiler);
// Else use simple node test iteration with predicate test.
iter = new ChildTestIterator(compiler, opPos, analysis);
}
}
// Is the iteration a one-step attribute pattern (i.e. select="@foo")?
else if (isOneStep && walksAttributes(analysis))
{
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("AttributeIterator", analysis, compiler);
// Then use a simple iteration of the attributes, with node test
// and predicate testing.
iter = new AttributeIterator(compiler, opPos, analysis);
}
else if(isOneStep && !walksFilteredList(analysis))
{
if( !walksNamespaces(analysis)
&& (walksInDocOrder(analysis) || isSet(analysis, BIT_PARENT)))
{
if (false || DEBUG_ITERATOR_CREATION)
diagnoseIterator("OneStepIteratorForward", analysis, compiler);
// Then use a simple iteration of the attributes, with node test
// and predicate testing.
iter = new OneStepIteratorForward(compiler, opPos, analysis);
}
else
{
if (false || DEBUG_ITERATOR_CREATION)
diagnoseIterator("OneStepIterator", analysis, compiler);
// Then use a simple iteration of the attributes, with node test
// and predicate testing.
iter = new OneStepIterator(compiler, opPos, analysis);
}
}
// Analysis of "//center":
// bits: 1001000000001010000000000000011
// count: 3
// root
// child:node()
// BIT_DESCENDANT_OR_SELF
// It's highly possible that we should have a seperate bit set for
// "//foo" patterns.
// For at least the time being, we can't optimize patterns like
// "//table[3]", because this has to be analyzed as
// "/descendant-or-self::node()/table[3]" in order for the indexes
// to work right.
else if (isOptimizableForDescendantIterator(compiler, firstStepPos, 0)
// && getStepCount(analysis) <= 3
// && walksDescendants(analysis)
// && walksSubtreeOnlyFromRootOrContext(analysis)
)
{
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("DescendantIterator", analysis, compiler);
iter = new DescendantIterator(compiler, opPos, analysis);
}
else
{
if(isNaturalDocOrder(compiler, firstStepPos, 0, analysis))
{
if (false || DEBUG_ITERATOR_CREATION)
{
diagnoseIterator("WalkingIterator", analysis, compiler);
}
iter = new WalkingIterator(compiler, opPos, analysis, true);
}
else
{
// if (DEBUG_ITERATOR_CREATION)
// diagnoseIterator("MatchPatternIterator", analysis, compiler);
//
// return new MatchPatternIterator(compiler, opPos, analysis);
if (DEBUG_ITERATOR_CREATION)
diagnoseIterator("WalkingIteratorSorted", analysis, compiler);
iter = new WalkingIteratorSorted(compiler, opPos, analysis, true);
}
}
if(iter instanceof LocPathIterator)
((LocPathIterator)iter).setIsTopLevel(isTopLevel);
return iter;
}
Special purpose function to see if we can optimize the pattern for
a DescendantIterator.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
Throws: Returns: 32 bits as an integer that give information about the location
path as a whole.
/**
* Special purpose function to see if we can optimize the pattern for
* a DescendantIterator.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
*
* @return 32 bits as an integer that give information about the location
* path as a whole.
*
* @throws javax.xml.transform.TransformerException
*/
public static int getAxisFromStep(
Compiler compiler, int stepOpCodePos)
throws javax.xml.transform.TransformerException
{
int stepType = compiler.getOp(stepOpCodePos);
switch (stepType)
{
case OpCodes.FROM_FOLLOWING :
return Axis.FOLLOWING;
case OpCodes.FROM_FOLLOWING_SIBLINGS :
return Axis.FOLLOWINGSIBLING;
case OpCodes.FROM_PRECEDING :
return Axis.PRECEDING;
case OpCodes.FROM_PRECEDING_SIBLINGS :
return Axis.PRECEDINGSIBLING;
case OpCodes.FROM_PARENT :
return Axis.PARENT;
case OpCodes.FROM_NAMESPACE :
return Axis.NAMESPACE;
case OpCodes.FROM_ANCESTORS :
return Axis.ANCESTOR;
case OpCodes.FROM_ANCESTORS_OR_SELF :
return Axis.ANCESTORORSELF;
case OpCodes.FROM_ATTRIBUTES :
return Axis.ATTRIBUTE;
case OpCodes.FROM_ROOT :
return Axis.ROOT;
case OpCodes.FROM_CHILDREN :
return Axis.CHILD;
case OpCodes.FROM_DESCENDANTS_OR_SELF :
return Axis.DESCENDANTORSELF;
case OpCodes.FROM_DESCENDANTS :
return Axis.DESCENDANT;
case OpCodes.FROM_SELF :
return Axis.SELF;
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
case OpCodes.OP_VARIABLE :
return Axis.FILTEREDLIST;
}
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
//+ stepType);
}
Get a corresponding BIT_XXX from an axis.
Params: - axis – One of Axis.ANCESTOR, etc.
Returns: One of BIT_ANCESTOR, etc.
/**
* Get a corresponding BIT_XXX from an axis.
* @param axis One of Axis.ANCESTOR, etc.
* @return One of BIT_ANCESTOR, etc.
*/
static public int getAnalysisBitFromAxes(int axis)
{
switch (axis) // Generate new traverser
{
case Axis.ANCESTOR :
return BIT_ANCESTOR;
case Axis.ANCESTORORSELF :
return BIT_ANCESTOR_OR_SELF;
case Axis.ATTRIBUTE :
return BIT_ATTRIBUTE;
case Axis.CHILD :
return BIT_CHILD;
case Axis.DESCENDANT :
return BIT_DESCENDANT;
case Axis.DESCENDANTORSELF :
return BIT_DESCENDANT_OR_SELF;
case Axis.FOLLOWING :
return BIT_FOLLOWING;
case Axis.FOLLOWINGSIBLING :
return BIT_FOLLOWING_SIBLING;
case Axis.NAMESPACE :
case Axis.NAMESPACEDECLS :
return BIT_NAMESPACE;
case Axis.PARENT :
return BIT_PARENT;
case Axis.PRECEDING :
return BIT_PRECEDING;
case Axis.PRECEDINGSIBLING :
return BIT_PRECEDING_SIBLING;
case Axis.SELF :
return BIT_SELF;
case Axis.ALLFROMNODE :
return BIT_DESCENDANT_OR_SELF;
// case Axis.PRECEDINGANDANCESTOR :
case Axis.DESCENDANTSFROMROOT :
case Axis.ALL :
case Axis.DESCENDANTSORSELFFROMROOT :
return BIT_ANY_DESCENDANT_FROM_ROOT;
case Axis.ROOT :
return BIT_ROOT;
case Axis.FILTEREDLIST :
return BIT_FILTER;
default :
return BIT_FILTER;
}
}
static boolean functionProximateOrContainsProximate(Compiler compiler,
int opPos)
{
int endFunc = opPos + compiler.getOp(opPos + 1) - 1;
opPos = OpMap.getFirstChildPos(opPos);
int funcID = compiler.getOp(opPos);
// System.out.println("funcID: "+funcID);
// System.out.println("opPos: "+opPos);
// System.out.println("endFunc: "+endFunc);
switch(funcID)
{
case FunctionTable.FUNC_LAST:
case FunctionTable.FUNC_POSITION:
return true;
default:
opPos++;
int i = 0;
for (int p = opPos; p < endFunc; p = compiler.getNextOpPos(p), i++)
{
int innerExprOpPos = p+2;
int argOp = compiler.getOp(innerExprOpPos);
boolean prox = isProximateInnerExpr(compiler, innerExprOpPos);
if(prox)
return true;
}
}
return false;
}
static boolean isProximateInnerExpr(Compiler compiler, int opPos)
{
int op = compiler.getOp(opPos);
int innerExprOpPos = opPos+2;
switch(op)
{
case OpCodes.OP_ARGUMENT:
if(isProximateInnerExpr(compiler, innerExprOpPos))
return true;
break;
case OpCodes.OP_VARIABLE:
case OpCodes.OP_NUMBERLIT:
case OpCodes.OP_LITERAL:
case OpCodes.OP_LOCATIONPATH:
break; // OK
case OpCodes.OP_FUNCTION:
boolean isProx = functionProximateOrContainsProximate(compiler, opPos);
if(isProx)
return true;
break;
case OpCodes.OP_GT:
case OpCodes.OP_GTE:
case OpCodes.OP_LT:
case OpCodes.OP_LTE:
case OpCodes.OP_EQUALS:
int leftPos = OpMap.getFirstChildPos(op);
int rightPos = compiler.getNextOpPos(leftPos);
isProx = isProximateInnerExpr(compiler, leftPos);
if(isProx)
return true;
isProx = isProximateInnerExpr(compiler, rightPos);
if(isProx)
return true;
break;
default:
return true; // be conservative...
}
return false;
}
Tell if the predicates need to have proximity knowledge.
/**
* Tell if the predicates need to have proximity knowledge.
*/
public static boolean mightBeProximate(Compiler compiler, int opPos, int stepType)
throws javax.xml.transform.TransformerException
{
boolean mightBeProximate = false;
int argLen;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
argLen = compiler.getArgLength(opPos);
break;
default :
argLen = compiler.getArgLengthOfStep(opPos);
}
int predPos = compiler.getFirstPredicateOpPos(opPos);
int count = 0;
while (OpCodes.OP_PREDICATE == compiler.getOp(predPos))
{
count++;
int innerExprOpPos = predPos+2;
int predOp = compiler.getOp(innerExprOpPos);
switch(predOp)
{
case OpCodes.OP_VARIABLE:
return true; // Would need more smarts to tell if this could be a number or not!
case OpCodes.OP_LOCATIONPATH:
// OK.
break;
case OpCodes.OP_NUMBER:
case OpCodes.OP_NUMBERLIT:
return true; // that's all she wrote!
case OpCodes.OP_FUNCTION:
boolean isProx
= functionProximateOrContainsProximate(compiler, innerExprOpPos);
if(isProx)
return true;
break;
case OpCodes.OP_GT:
case OpCodes.OP_GTE:
case OpCodes.OP_LT:
case OpCodes.OP_LTE:
case OpCodes.OP_EQUALS:
int leftPos = OpMap.getFirstChildPos(innerExprOpPos);
int rightPos = compiler.getNextOpPos(leftPos);
isProx = isProximateInnerExpr(compiler, leftPos);
if(isProx)
return true;
isProx = isProximateInnerExpr(compiler, rightPos);
if(isProx)
return true;
break;
default:
return true; // be conservative...
}
predPos = compiler.getNextOpPos(predPos);
}
return mightBeProximate;
}
Special purpose function to see if we can optimize the pattern for
a DescendantIterator.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
- stepIndex – The top-level step index withing the iterator.
Throws: Returns: 32 bits as an integer that give information about the location
path as a whole.
/**
* Special purpose function to see if we can optimize the pattern for
* a DescendantIterator.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
* @param stepIndex The top-level step index withing the iterator.
*
* @return 32 bits as an integer that give information about the location
* path as a whole.
*
* @throws javax.xml.transform.TransformerException
*/
private static boolean isOptimizableForDescendantIterator(
Compiler compiler, int stepOpCodePos, int stepIndex)
throws javax.xml.transform.TransformerException
{
int stepType;
int stepCount = 0;
boolean foundDorDS = false;
boolean foundSelf = false;
boolean foundDS = false;
int nodeTestType = OpCodes.NODETYPE_NODE;
while (OpCodes.ENDOP != (stepType = compiler.getOp(stepOpCodePos)))
{
// The DescendantIterator can only do one node test. If there's more
// than one, use another iterator.
if(nodeTestType != OpCodes.NODETYPE_NODE && nodeTestType != OpCodes.NODETYPE_ROOT)
return false;
stepCount++;
if(stepCount > 3)
return false;
boolean mightBeProximate = mightBeProximate(compiler, stepOpCodePos, stepType);
if(mightBeProximate)
return false;
switch (stepType)
{
case OpCodes.FROM_FOLLOWING :
case OpCodes.FROM_FOLLOWING_SIBLINGS :
case OpCodes.FROM_PRECEDING :
case OpCodes.FROM_PRECEDING_SIBLINGS :
case OpCodes.FROM_PARENT :
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
case OpCodes.FROM_NAMESPACE :
case OpCodes.FROM_ANCESTORS :
case OpCodes.FROM_ANCESTORS_OR_SELF :
case OpCodes.FROM_ATTRIBUTES :
case OpCodes.MATCH_ATTRIBUTE :
case OpCodes.MATCH_ANY_ANCESTOR :
case OpCodes.MATCH_IMMEDIATE_ANCESTOR :
return false;
case OpCodes.FROM_ROOT :
if(1 != stepCount)
return false;
break;
case OpCodes.FROM_CHILDREN :
if(!foundDS && !(foundDorDS && foundSelf))
return false;
break;
case OpCodes.FROM_DESCENDANTS_OR_SELF :
foundDS = true;
case OpCodes.FROM_DESCENDANTS :
if(3 == stepCount)
return false;
foundDorDS = true;
break;
case OpCodes.FROM_SELF :
if(1 != stepCount)
return false;
foundSelf = true;
break;
default :
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
// + stepType);
}
nodeTestType = compiler.getStepTestType(stepOpCodePos);
int nextStepOpCodePos = compiler.getNextStepPos(stepOpCodePos);
if (nextStepOpCodePos < 0)
break;
if(OpCodes.ENDOP != compiler.getOp(nextStepOpCodePos))
{
if(compiler.countPredicates(stepOpCodePos) > 0)
{
return false;
}
}
stepOpCodePos = nextStepOpCodePos;
}
return true;
}
Analyze the location path and return 32 bits that give information about
the location path as a whole. See the BIT_XXX constants for meaning about
each of the bits.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
- stepIndex – The top-level step index withing the iterator.
Throws: Returns: 32 bits as an integer that give information about the location
path as a whole.
/**
* Analyze the location path and return 32 bits that give information about
* the location path as a whole. See the BIT_XXX constants for meaning about
* each of the bits.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
* @param stepIndex The top-level step index withing the iterator.
*
* @return 32 bits as an integer that give information about the location
* path as a whole.
*
* @throws javax.xml.transform.TransformerException
*/
private static int analyze(
Compiler compiler, int stepOpCodePos, int stepIndex)
throws javax.xml.transform.TransformerException
{
int stepType;
int stepCount = 0;
int analysisResult = 0x00000000; // 32 bits of analysis
while (OpCodes.ENDOP != (stepType = compiler.getOp(stepOpCodePos)))
{
stepCount++;
// String namespace = compiler.getStepNS(stepOpCodePos);
// boolean isNSWild = (null != namespace)
// ? namespace.equals(NodeTest.WILD) : false;
// String localname = compiler.getStepLocalName(stepOpCodePos);
// boolean isWild = (null != localname) ? localname.equals(NodeTest.WILD) : false;
boolean predAnalysis = analyzePredicate(compiler, stepOpCodePos,
stepType);
if (predAnalysis)
analysisResult |= BIT_PREDICATE;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
analysisResult |= BIT_FILTER;
break;
case OpCodes.FROM_ROOT :
analysisResult |= BIT_ROOT;
break;
case OpCodes.FROM_ANCESTORS :
analysisResult |= BIT_ANCESTOR;
break;
case OpCodes.FROM_ANCESTORS_OR_SELF :
analysisResult |= BIT_ANCESTOR_OR_SELF;
break;
case OpCodes.FROM_ATTRIBUTES :
analysisResult |= BIT_ATTRIBUTE;
break;
case OpCodes.FROM_NAMESPACE :
analysisResult |= BIT_NAMESPACE;
break;
case OpCodes.FROM_CHILDREN :
analysisResult |= BIT_CHILD;
break;
case OpCodes.FROM_DESCENDANTS :
analysisResult |= BIT_DESCENDANT;
break;
case OpCodes.FROM_DESCENDANTS_OR_SELF :
// Use a special bit to to make sure we get the right analysis of "//foo".
if (2 == stepCount && BIT_ROOT == analysisResult)
{
analysisResult |= BIT_ANY_DESCENDANT_FROM_ROOT;
}
analysisResult |= BIT_DESCENDANT_OR_SELF;
break;
case OpCodes.FROM_FOLLOWING :
analysisResult |= BIT_FOLLOWING;
break;
case OpCodes.FROM_FOLLOWING_SIBLINGS :
analysisResult |= BIT_FOLLOWING_SIBLING;
break;
case OpCodes.FROM_PRECEDING :
analysisResult |= BIT_PRECEDING;
break;
case OpCodes.FROM_PRECEDING_SIBLINGS :
analysisResult |= BIT_PRECEDING_SIBLING;
break;
case OpCodes.FROM_PARENT :
analysisResult |= BIT_PARENT;
break;
case OpCodes.FROM_SELF :
analysisResult |= BIT_SELF;
break;
case OpCodes.MATCH_ATTRIBUTE :
analysisResult |= (BIT_MATCH_PATTERN | BIT_ATTRIBUTE);
break;
case OpCodes.MATCH_ANY_ANCESTOR :
analysisResult |= (BIT_MATCH_PATTERN | BIT_ANCESTOR);
break;
case OpCodes.MATCH_IMMEDIATE_ANCESTOR :
analysisResult |= (BIT_MATCH_PATTERN | BIT_PARENT);
break;
default :
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
//+ stepType);
}
if (OpCodes.NODETYPE_NODE == compiler.getOp(stepOpCodePos + 3)) // child::node()
{
analysisResult |= BIT_NODETEST_ANY;
}
stepOpCodePos = compiler.getNextStepPos(stepOpCodePos);
if (stepOpCodePos < 0)
break;
}
analysisResult |= (stepCount & BITS_COUNT);
return analysisResult;
}
Tell if the given axis goes downword. Bogus name, if you can think of
a better one, please do tell. This really has to do with inverting
attribute axis.
Params: - axis – One of Axis.XXX.
Returns: true if the axis is not a child axis and does not go up from
the axis root.
/**
* Tell if the given axis goes downword. Bogus name, if you can think of
* a better one, please do tell. This really has to do with inverting
* attribute axis.
* @param axis One of Axis.XXX.
* @return true if the axis is not a child axis and does not go up from
* the axis root.
*/
public static boolean isDownwardAxisOfMany(int axis)
{
return ((Axis.DESCENDANTORSELF == axis) ||
(Axis.DESCENDANT == axis)
|| (Axis.FOLLOWING == axis)
// || (Axis.FOLLOWINGSIBLING == axis)
|| (Axis.PRECEDING == axis)
// || (Axis.PRECEDINGSIBLING == axis)
);
}
Read a LocationPath
as a generalized match pattern. What this means is that the LocationPath
is read backwards, as a test on a given node, to see if it matches the
criteria of the selection, and ends up at the context node. Essentially,
this is a backwards query from a given node, to find the context node.
So, the selection "foo/daz[2]" is, in non-abreviated expanded syntax,
"self::node()/following-sibling::foo/child::daz[position()=2]".
Taking this as a match pattern for a probable node, it works out to
"self::daz/parent::foo[child::daz[position()=2 and isPrevStepNode()]
precedingSibling::node()[isContextNodeOfLocationPath()]", adding magic
isPrevStepNode and isContextNodeOfLocationPath operations. Predicates in
the location path have to be executed by the following step,
because they have to know the context of their execution.
Params: - mpi – The MatchPatternIterator to which the steps will be attached.
- compiler – The compiler that holds the syntax tree/op map to
construct from.
- stepOpCodePos – The current op code position within the opmap.
- stepIndex – The top-level step index withing the iterator.
Throws: Returns: A StepPattern object, which may contain relative StepPatterns.
/**
* Read a <a href="http://www.w3.org/TR/xpath#location-paths">LocationPath</a>
* as a generalized match pattern. What this means is that the LocationPath
* is read backwards, as a test on a given node, to see if it matches the
* criteria of the selection, and ends up at the context node. Essentially,
* this is a backwards query from a given node, to find the context node.
* <p>So, the selection "foo/daz[2]" is, in non-abreviated expanded syntax,
* "self::node()/following-sibling::foo/child::daz[position()=2]".
* Taking this as a match pattern for a probable node, it works out to
* "self::daz/parent::foo[child::daz[position()=2 and isPrevStepNode()]
* precedingSibling::node()[isContextNodeOfLocationPath()]", adding magic
* isPrevStepNode and isContextNodeOfLocationPath operations. Predicates in
* the location path have to be executed by the following step,
* because they have to know the context of their execution.
*
* @param mpi The MatchPatternIterator to which the steps will be attached.
* @param compiler The compiler that holds the syntax tree/op map to
* construct from.
* @param stepOpCodePos The current op code position within the opmap.
* @param stepIndex The top-level step index withing the iterator.
*
* @return A StepPattern object, which may contain relative StepPatterns.
*
* @throws javax.xml.transform.TransformerException
*/
static StepPattern loadSteps(
MatchPatternIterator mpi, Compiler compiler, int stepOpCodePos,
int stepIndex)
throws javax.xml.transform.TransformerException
{
if (DEBUG_PATTERN_CREATION)
{
System.out.println("================");
System.out.println("loadSteps for: "+compiler.getPatternString());
}
int stepType;
StepPattern step = null;
StepPattern firstStep = null, prevStep = null;
int analysis = analyze(compiler, stepOpCodePos, stepIndex);
while (OpCodes.ENDOP != (stepType = compiler.getOp(stepOpCodePos)))
{
step = createDefaultStepPattern(compiler, stepOpCodePos, mpi, analysis,
firstStep, prevStep);
if (null == firstStep)
{
firstStep = step;
}
else
{
//prevStep.setNextWalker(step);
step.setRelativePathPattern(prevStep);
}
prevStep = step;
stepOpCodePos = compiler.getNextStepPos(stepOpCodePos);
if (stepOpCodePos < 0)
break;
}
int axis = Axis.SELF;
int paxis = Axis.SELF;
StepPattern tail = step;
for (StepPattern pat = step; null != pat;
pat = pat.getRelativePathPattern())
{
int nextAxis = pat.getAxis();
//int nextPaxis = pat.getPredicateAxis();
pat.setAxis(axis);
// The predicate axis can't be moved!!! Test Axes103
// pat.setPredicateAxis(paxis);
// If we have an attribute or namespace axis that went up, then
// it won't find the attribute in the inverse, since the select-to-match
// axes are not invertable (an element is a parent of an attribute, but
// and attribute is not a child of an element).
// If we don't do the magic below, then "@*/ancestor-or-self::*" gets
// inverted for match to "self::*/descendant-or-self::@*/parent::node()",
// which obviously won't work.
// So we will rewrite this as:
// "self::*/descendant-or-self::*/attribute::*/parent::node()"
// Child has to be rewritten a little differently:
// select: "@*/parent::*"
// inverted match: "self::*/child::@*/parent::node()"
// rewrite: "self::*/attribute::*/parent::node()"
// Axes that go down in the select, do not have to have special treatment
// in the rewrite. The following inverted match will still not select
// anything.
// select: "@*/child::*"
// inverted match: "self::*/parent::@*/parent::node()"
// Lovely business, this.
// -sb
int whatToShow = pat.getWhatToShow();
if(whatToShow == DTMFilter.SHOW_ATTRIBUTE ||
whatToShow == DTMFilter.SHOW_NAMESPACE)
{
int newAxis = (whatToShow == DTMFilter.SHOW_ATTRIBUTE) ?
Axis.ATTRIBUTE : Axis.NAMESPACE;
if(isDownwardAxisOfMany(axis))
{
StepPattern attrPat = new StepPattern(whatToShow,
pat.getNamespace(),
pat.getLocalName(),
//newAxis, pat.getPredicateAxis);
newAxis, 0); // don't care about the predicate axis
XNumber score = pat.getStaticScore();
pat.setNamespace(null);
pat.setLocalName(NodeTest.WILD);
attrPat.setPredicates(pat.getPredicates());
pat.setPredicates(null);
pat.setWhatToShow(DTMFilter.SHOW_ELEMENT);
StepPattern rel = pat.getRelativePathPattern();
pat.setRelativePathPattern(attrPat);
attrPat.setRelativePathPattern(rel);
attrPat.setStaticScore(score);
// This is needed to inverse a following pattern, because of the
// wacky Xalan rules for following from an attribute. See axes108.
// By these rules, following from an attribute is not strictly
// inverseable.
if(Axis.PRECEDING == pat.getAxis())
pat.setAxis(Axis.PRECEDINGANDANCESTOR);
else if(Axis.DESCENDANT == pat.getAxis())
pat.setAxis(Axis.DESCENDANTORSELF);
pat = attrPat;
}
else if(Axis.CHILD == pat.getAxis())
{
// In this case just change the axis.
// pat.setWhatToShow(whatToShow);
pat.setAxis(Axis.ATTRIBUTE);
}
}
axis = nextAxis;
//paxis = nextPaxis;
tail = pat;
}
if(axis < Axis.ALL)
{
StepPattern selfPattern = new ContextMatchStepPattern(axis, paxis);
// We need to keep the new nodetest from affecting the score...
XNumber score = tail.getStaticScore();
tail.setRelativePathPattern(selfPattern);
tail.setStaticScore(score);
selfPattern.setStaticScore(score);
}
if (DEBUG_PATTERN_CREATION)
{
System.out.println("Done loading steps: "+step.toString());
System.out.println("");
}
return step; // start from last pattern?? //firstStep;
}
Create a StepPattern that is contained within a LocationPath.
Params: - compiler – The compiler that holds the syntax tree/op map to
construct from.
- stepOpCodePos – The current op code position within the opmap.
- mpi – The MatchPatternIterator to which the steps will be attached.
- analysis – 32 bits of analysis, from which the type of AxesWalker
may be influenced.
- tail – The step that is the first step analyzed, but the last
step in the relative match linked list, i.e. the tail.
May be null.
- head – The step that is the current head of the relative
match step linked list.
May be null.
Throws: Returns: the head of the list.
/**
* Create a StepPattern that is contained within a LocationPath.
*
*
* @param compiler The compiler that holds the syntax tree/op map to
* construct from.
* @param stepOpCodePos The current op code position within the opmap.
* @param mpi The MatchPatternIterator to which the steps will be attached.
* @param analysis 32 bits of analysis, from which the type of AxesWalker
* may be influenced.
* @param tail The step that is the first step analyzed, but the last
* step in the relative match linked list, i.e. the tail.
* May be null.
* @param head The step that is the current head of the relative
* match step linked list.
* May be null.
*
* @return the head of the list.
*
* @throws javax.xml.transform.TransformerException
*/
private static StepPattern createDefaultStepPattern(
Compiler compiler, int opPos, MatchPatternIterator mpi,
int analysis, StepPattern tail, StepPattern head)
throws javax.xml.transform.TransformerException
{
int stepType = compiler.getOp(opPos);
boolean simpleInit = false;
boolean prevIsOneStepDown = true;
int whatToShow = compiler.getWhatToShow(opPos);
StepPattern ai = null;
int axis, predicateAxis;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
prevIsOneStepDown = false;
Expression expr;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
expr = compiler.compile(opPos);
break;
default :
expr = compiler.compile(opPos + 2);
}
axis = Axis.FILTEREDLIST;
predicateAxis = Axis.FILTEREDLIST;
ai = new FunctionPattern(expr, axis, predicateAxis);
simpleInit = true;
break;
case OpCodes.FROM_ROOT :
whatToShow = DTMFilter.SHOW_DOCUMENT
| DTMFilter.SHOW_DOCUMENT_FRAGMENT;
axis = Axis.ROOT;
predicateAxis = Axis.ROOT;
ai = new StepPattern(DTMFilter.SHOW_DOCUMENT |
DTMFilter.SHOW_DOCUMENT_FRAGMENT,
axis, predicateAxis);
break;
case OpCodes.FROM_ATTRIBUTES :
whatToShow = DTMFilter.SHOW_ATTRIBUTE;
axis = Axis.PARENT;
predicateAxis = Axis.ATTRIBUTE;
// ai = new StepPattern(whatToShow, Axis.SELF, Axis.SELF);
break;
case OpCodes.FROM_NAMESPACE :
whatToShow = DTMFilter.SHOW_NAMESPACE;
axis = Axis.PARENT;
predicateAxis = Axis.NAMESPACE;
// ai = new StepPattern(whatToShow, axis, predicateAxis);
break;
case OpCodes.FROM_ANCESTORS :
axis = Axis.DESCENDANT;
predicateAxis = Axis.ANCESTOR;
break;
case OpCodes.FROM_CHILDREN :
axis = Axis.PARENT;
predicateAxis = Axis.CHILD;
break;
case OpCodes.FROM_ANCESTORS_OR_SELF :
axis = Axis.DESCENDANTORSELF;
predicateAxis = Axis.ANCESTORORSELF;
break;
case OpCodes.FROM_SELF :
axis = Axis.SELF;
predicateAxis = Axis.SELF;
break;
case OpCodes.FROM_PARENT :
axis = Axis.CHILD;
predicateAxis = Axis.PARENT;
break;
case OpCodes.FROM_PRECEDING_SIBLINGS :
axis = Axis.FOLLOWINGSIBLING;
predicateAxis = Axis.PRECEDINGSIBLING;
break;
case OpCodes.FROM_PRECEDING :
axis = Axis.FOLLOWING;
predicateAxis = Axis.PRECEDING;
break;
case OpCodes.FROM_FOLLOWING_SIBLINGS :
axis = Axis.PRECEDINGSIBLING;
predicateAxis = Axis.FOLLOWINGSIBLING;
break;
case OpCodes.FROM_FOLLOWING :
axis = Axis.PRECEDING;
predicateAxis = Axis.FOLLOWING;
break;
case OpCodes.FROM_DESCENDANTS_OR_SELF :
axis = Axis.ANCESTORORSELF;
predicateAxis = Axis.DESCENDANTORSELF;
break;
case OpCodes.FROM_DESCENDANTS :
axis = Axis.ANCESTOR;
predicateAxis = Axis.DESCENDANT;
break;
default :
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
//+ stepType);
}
if(null == ai)
{
whatToShow = compiler.getWhatToShow(opPos); // %REVIEW%
ai = new StepPattern(whatToShow, compiler.getStepNS(opPos),
compiler.getStepLocalName(opPos),
axis, predicateAxis);
}
if (false || DEBUG_PATTERN_CREATION)
{
System.out.print("new step: "+ ai);
System.out.print(", axis: " + Axis.getNames(ai.getAxis()));
System.out.print(", predAxis: " + Axis.getNames(ai.getAxis()));
System.out.print(", what: ");
System.out.print(" ");
ai.debugWhatToShow(ai.getWhatToShow());
}
int argLen = compiler.getFirstPredicateOpPos(opPos);
ai.setPredicates(compiler.getCompiledPredicates(argLen));
return ai;
}
Analyze a step and give information about it's predicates. Right now this
just returns true or false if the step has a predicate.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- opPos – The opcode position for the step.
- stepType – The type of step, one of OP_GROUP, etc.
Throws: Returns: true if step has a predicate.
/**
* Analyze a step and give information about it's predicates. Right now this
* just returns true or false if the step has a predicate.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param opPos The opcode position for the step.
* @param stepType The type of step, one of OP_GROUP, etc.
*
* @return true if step has a predicate.
*
* @throws javax.xml.transform.TransformerException
*/
static boolean analyzePredicate(Compiler compiler, int opPos, int stepType)
throws javax.xml.transform.TransformerException
{
int argLen;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
argLen = compiler.getArgLength(opPos);
break;
default :
argLen = compiler.getArgLengthOfStep(opPos);
}
int pos = compiler.getFirstPredicateOpPos(opPos);
int nPredicates = compiler.countPredicates(pos);
return (nPredicates > 0) ? true : false;
}
Create the proper Walker from the axes type.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- opPos – The opcode position for the step.
- lpi – The owning location path iterator.
- analysis – 32 bits of analysis, from which the type of AxesWalker
may be influenced.
Throws: - RuntimeException – if the input is bad.
Returns: non-null reference to AxesWalker derivative.
/**
* Create the proper Walker from the axes type.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param opPos The opcode position for the step.
* @param lpi The owning location path iterator.
* @param analysis 32 bits of analysis, from which the type of AxesWalker
* may be influenced.
*
* @return non-null reference to AxesWalker derivative.
* @throws RuntimeException if the input is bad.
*/
private static AxesWalker createDefaultWalker(Compiler compiler, int opPos,
WalkingIterator lpi, int analysis)
{
AxesWalker ai = null;
int stepType = compiler.getOp(opPos);
/*
System.out.println("0: "+compiler.getOp(opPos));
System.out.println("1: "+compiler.getOp(opPos+1));
System.out.println("2: "+compiler.getOp(opPos+2));
System.out.println("3: "+compiler.getOp(opPos+3));
System.out.println("4: "+compiler.getOp(opPos+4));
System.out.println("5: "+compiler.getOp(opPos+5));
*/
boolean simpleInit = false;
int totalNumberWalkers = (analysis & BITS_COUNT);
boolean prevIsOneStepDown = true;
switch (stepType)
{
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
prevIsOneStepDown = false;
if (DEBUG_WALKER_CREATION)
System.out.println("new walker: FilterExprWalker: " + analysis
+ ", " + compiler.toString());
ai = new FilterExprWalker(lpi);
simpleInit = true;
break;
case OpCodes.FROM_ROOT :
ai = new AxesWalker(lpi, Axis.ROOT);
break;
case OpCodes.FROM_ANCESTORS :
prevIsOneStepDown = false;
ai = new ReverseAxesWalker(lpi, Axis.ANCESTOR);
break;
case OpCodes.FROM_ANCESTORS_OR_SELF :
prevIsOneStepDown = false;
ai = new ReverseAxesWalker(lpi, Axis.ANCESTORORSELF);
break;
case OpCodes.FROM_ATTRIBUTES :
ai = new AxesWalker(lpi, Axis.ATTRIBUTE);
break;
case OpCodes.FROM_NAMESPACE :
ai = new AxesWalker(lpi, Axis.NAMESPACE);
break;
case OpCodes.FROM_CHILDREN :
ai = new AxesWalker(lpi, Axis.CHILD);
break;
case OpCodes.FROM_DESCENDANTS :
prevIsOneStepDown = false;
ai = new AxesWalker(lpi, Axis.DESCENDANT);
break;
case OpCodes.FROM_DESCENDANTS_OR_SELF :
prevIsOneStepDown = false;
ai = new AxesWalker(lpi, Axis.DESCENDANTORSELF);
break;
case OpCodes.FROM_FOLLOWING :
prevIsOneStepDown = false;
ai = new AxesWalker(lpi, Axis.FOLLOWING);
break;
case OpCodes.FROM_FOLLOWING_SIBLINGS :
prevIsOneStepDown = false;
ai = new AxesWalker(lpi, Axis.FOLLOWINGSIBLING);
break;
case OpCodes.FROM_PRECEDING :
prevIsOneStepDown = false;
ai = new ReverseAxesWalker(lpi, Axis.PRECEDING);
break;
case OpCodes.FROM_PRECEDING_SIBLINGS :
prevIsOneStepDown = false;
ai = new ReverseAxesWalker(lpi, Axis.PRECEDINGSIBLING);
break;
case OpCodes.FROM_PARENT :
prevIsOneStepDown = false;
ai = new ReverseAxesWalker(lpi, Axis.PARENT);
break;
case OpCodes.FROM_SELF :
ai = new AxesWalker(lpi, Axis.SELF);
break;
default :
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
//+ stepType);
}
if (simpleInit)
{
ai.initNodeTest(DTMFilter.SHOW_ALL);
}
else
{
int whatToShow = compiler.getWhatToShow(opPos);
/*
System.out.print("construct: ");
NodeTest.debugWhatToShow(whatToShow);
System.out.println("or stuff: "+(whatToShow & (DTMFilter.SHOW_ATTRIBUTE
| DTMFilter.SHOW_ELEMENT
| DTMFilter.SHOW_PROCESSING_INSTRUCTION)));
*/
if ((0 == (whatToShow
& (DTMFilter.SHOW_ATTRIBUTE | DTMFilter.SHOW_NAMESPACE | DTMFilter.SHOW_ELEMENT
| DTMFilter.SHOW_PROCESSING_INSTRUCTION))) || (whatToShow == DTMFilter.SHOW_ALL))
ai.initNodeTest(whatToShow);
else
{
ai.initNodeTest(whatToShow, compiler.getStepNS(opPos),
compiler.getStepLocalName(opPos));
}
}
return ai;
}
public static String getAnalysisString(int analysis)
{
StringBuffer buf = new StringBuffer();
buf.append("count: "+getStepCount(analysis)+" ");
if((analysis & BIT_NODETEST_ANY) != 0)
{
buf.append("NTANY|");
}
if((analysis & BIT_PREDICATE) != 0)
{
buf.append("PRED|");
}
if((analysis & BIT_ANCESTOR) != 0)
{
buf.append("ANC|");
}
if((analysis & BIT_ANCESTOR_OR_SELF) != 0)
{
buf.append("ANCOS|");
}
if((analysis & BIT_ATTRIBUTE) != 0)
{
buf.append("ATTR|");
}
if((analysis & BIT_CHILD) != 0)
{
buf.append("CH|");
}
if((analysis & BIT_DESCENDANT) != 0)
{
buf.append("DESC|");
}
if((analysis & BIT_DESCENDANT_OR_SELF) != 0)
{
buf.append("DESCOS|");
}
if((analysis & BIT_FOLLOWING) != 0)
{
buf.append("FOL|");
}
if((analysis & BIT_FOLLOWING_SIBLING) != 0)
{
buf.append("FOLS|");
}
if((analysis & BIT_NAMESPACE) != 0)
{
buf.append("NS|");
}
if((analysis & BIT_PARENT) != 0)
{
buf.append("P|");
}
if((analysis & BIT_PRECEDING) != 0)
{
buf.append("PREC|");
}
if((analysis & BIT_PRECEDING_SIBLING) != 0)
{
buf.append("PRECS|");
}
if((analysis & BIT_SELF) != 0)
{
buf.append(".|");
}
if((analysis & BIT_FILTER) != 0)
{
buf.append("FLT|");
}
if((analysis & BIT_ROOT) != 0)
{
buf.append("R|");
}
return buf.toString();
}
Set to true for diagnostics about walker creation /** Set to true for diagnostics about walker creation */
static final boolean DEBUG_PATTERN_CREATION = false;
Set to true for diagnostics about walker creation /** Set to true for diagnostics about walker creation */
static final boolean DEBUG_WALKER_CREATION = false;
Set to true for diagnostics about iterator creation /** Set to true for diagnostics about iterator creation */
static final boolean DEBUG_ITERATOR_CREATION = false;
public static boolean hasPredicate(int analysis)
{
return (0 != (analysis & BIT_PREDICATE));
}
public static boolean isWild(int analysis)
{
return (0 != (analysis & BIT_NODETEST_ANY));
}
public static boolean walksAncestors(int analysis)
{
return isSet(analysis, BIT_ANCESTOR | BIT_ANCESTOR_OR_SELF);
}
public static boolean walksAttributes(int analysis)
{
return (0 != (analysis & BIT_ATTRIBUTE));
}
public static boolean walksNamespaces(int analysis)
{
return (0 != (analysis & BIT_NAMESPACE));
}
public static boolean walksChildren(int analysis)
{
return (0 != (analysis & BIT_CHILD));
}
public static boolean walksDescendants(int analysis)
{
return isSet(analysis, BIT_DESCENDANT | BIT_DESCENDANT_OR_SELF);
}
public static boolean walksSubtree(int analysis)
{
return isSet(analysis, BIT_DESCENDANT | BIT_DESCENDANT_OR_SELF | BIT_CHILD);
}
public static boolean walksSubtreeOnlyMaybeAbsolute(int analysis)
{
return walksSubtree(analysis)
&& !walksExtraNodes(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
;
}
public static boolean walksSubtreeOnly(int analysis)
{
return walksSubtreeOnlyMaybeAbsolute(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean walksFilteredList(int analysis)
{
return isSet(analysis, BIT_FILTER);
}
public static boolean walksSubtreeOnlyFromRootOrContext(int analysis)
{
return walksSubtree(analysis)
&& !walksExtraNodes(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& !isSet(analysis, BIT_FILTER)
;
}
public static boolean walksInDocOrder(int analysis)
{
return (walksSubtreeOnlyMaybeAbsolute(analysis)
|| walksExtraNodesOnly(analysis)
|| walksFollowingOnlyMaybeAbsolute(analysis))
&& !isSet(analysis, BIT_FILTER)
;
}
public static boolean walksFollowingOnlyMaybeAbsolute(int analysis)
{
return isSet(analysis, BIT_SELF | BIT_FOLLOWING_SIBLING | BIT_FOLLOWING)
&& !walksSubtree(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
;
}
public static boolean walksUp(int analysis)
{
return isSet(analysis, BIT_PARENT | BIT_ANCESTOR | BIT_ANCESTOR_OR_SELF);
}
public static boolean walksSideways(int analysis)
{
return isSet(analysis, BIT_FOLLOWING | BIT_FOLLOWING_SIBLING |
BIT_PRECEDING | BIT_PRECEDING_SIBLING);
}
public static boolean walksExtraNodes(int analysis)
{
return isSet(analysis, BIT_NAMESPACE | BIT_ATTRIBUTE);
}
public static boolean walksExtraNodesOnly(int analysis)
{
return walksExtraNodes(analysis)
&& !isSet(analysis, BIT_SELF)
&& !walksSubtree(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean isAbsolute(int analysis)
{
return isSet(analysis, BIT_ROOT | BIT_FILTER);
}
public static boolean walksChildrenOnly(int analysis)
{
return walksChildren(analysis)
&& !isSet(analysis, BIT_SELF)
&& !walksExtraNodes(analysis)
&& !walksDescendants(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& (!isAbsolute(analysis) || isSet(analysis, BIT_ROOT))
;
}
public static boolean walksChildrenAndExtraAndSelfOnly(int analysis)
{
return walksChildren(analysis)
&& !walksDescendants(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& (!isAbsolute(analysis) || isSet(analysis, BIT_ROOT))
;
}
public static boolean walksDescendantsAndExtraAndSelfOnly(int analysis)
{
return !walksChildren(analysis)
&& walksDescendants(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& (!isAbsolute(analysis) || isSet(analysis, BIT_ROOT))
;
}
public static boolean walksSelfOnly(int analysis)
{
return isSet(analysis, BIT_SELF)
&& !walksSubtree(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean walksUpOnly(int analysis)
{
return !walksSubtree(analysis)
&& walksUp(analysis)
&& !walksSideways(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean walksDownOnly(int analysis)
{
return walksSubtree(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean walksDownExtraOnly(int analysis)
{
return walksSubtree(analysis) && walksExtraNodes(analysis)
&& !walksUp(analysis)
&& !walksSideways(analysis)
&& !isAbsolute(analysis)
;
}
public static boolean canSkipSubtrees(int analysis)
{
return isSet(analysis, BIT_CHILD) | walksSideways(analysis);
}
public static boolean canCrissCross(int analysis)
{
// This could be done faster. Coded for clarity.
if(walksSelfOnly(analysis))
return false;
else if(walksDownOnly(analysis) && !canSkipSubtrees(analysis))
return false;
else if(walksChildrenAndExtraAndSelfOnly(analysis))
return false;
else if(walksDescendantsAndExtraAndSelfOnly(analysis))
return false;
else if(walksUpOnly(analysis))
return false;
else if(walksExtraNodesOnly(analysis))
return false;
else if(walksSubtree(analysis)
&& (walksSideways(analysis)
|| walksUp(analysis)
|| canSkipSubtrees(analysis)))
return true;
else
return false;
}
Tell if the pattern can be 'walked' with the iteration steps in natural
document order, without duplicates.
Params: - analysis – The general analysis of the pattern.
Throws: Returns: true if the walk can be done in natural order.
/**
* Tell if the pattern can be 'walked' with the iteration steps in natural
* document order, without duplicates.
*
* @param analysis The general analysis of the pattern.
*
* @return true if the walk can be done in natural order.
*
* @throws javax.xml.transform.TransformerException
*/
static public boolean isNaturalDocOrder(int analysis)
{
if(canCrissCross(analysis) || isSet(analysis, BIT_NAMESPACE) ||
walksFilteredList(analysis))
return false;
if(walksInDocOrder(analysis))
return true;
return false;
}
Tell if the pattern can be 'walked' with the iteration steps in natural
document order, without duplicates.
Params: - compiler – non-null reference to compiler object that has processed
the XPath operations into an opcode map.
- stepOpCodePos – The opcode position for the step.
- stepIndex – The top-level step index withing the iterator.
- analysis – The general analysis of the pattern.
Throws: Returns: true if the walk can be done in natural order.
/**
* Tell if the pattern can be 'walked' with the iteration steps in natural
* document order, without duplicates.
*
* @param compiler non-null reference to compiler object that has processed
* the XPath operations into an opcode map.
* @param stepOpCodePos The opcode position for the step.
* @param stepIndex The top-level step index withing the iterator.
* @param analysis The general analysis of the pattern.
*
* @return true if the walk can be done in natural order.
*
* @throws javax.xml.transform.TransformerException
*/
private static boolean isNaturalDocOrder(
Compiler compiler, int stepOpCodePos, int stepIndex, int analysis)
throws javax.xml.transform.TransformerException
{
if(canCrissCross(analysis))
return false;
// Namespaces can present some problems, so just punt if we're looking for
// these.
if(isSet(analysis, BIT_NAMESPACE))
return false;
// The following, preceding, following-sibling, and preceding sibling can
// be found in doc order if we get to this point, but if they occur
// together, they produce
// duplicates, so it's better for us to eliminate this case so we don't
// have to check for duplicates during runtime if we're using a
// WalkingIterator.
if(isSet(analysis, BIT_FOLLOWING | BIT_FOLLOWING_SIBLING) &&
isSet(analysis, BIT_PRECEDING | BIT_PRECEDING_SIBLING))
return false;
// OK, now we have to check for select="@*/axis::*" patterns, which
// can also cause duplicates to happen. But select="axis*/@::*" patterns
// are OK, as are select="@foo/axis::*" patterns.
// Unfortunately, we can't do this just via the analysis bits.
int stepType;
int stepCount = 0;
boolean foundWildAttribute = false;
// Steps that can traverse anything other than down a
// subtree or that can produce duplicates when used in
// combonation are counted with this variable.
int potentialDuplicateMakingStepCount = 0;
while (OpCodes.ENDOP != (stepType = compiler.getOp(stepOpCodePos)))
{
stepCount++;
switch (stepType)
{
case OpCodes.FROM_ATTRIBUTES :
case OpCodes.MATCH_ATTRIBUTE :
if(foundWildAttribute) // Maybe not needed, but be safe.
return false;
// This doesn't seem to work as a test for wild card. Hmph.
// int nodeTestType = compiler.getStepTestType(stepOpCodePos);
String localName = compiler.getStepLocalName(stepOpCodePos);
// System.err.println("localName: "+localName);
if(localName.equals("*"))
{
foundWildAttribute = true;
}
break;
case OpCodes.FROM_FOLLOWING :
case OpCodes.FROM_FOLLOWING_SIBLINGS :
case OpCodes.FROM_PRECEDING :
case OpCodes.FROM_PRECEDING_SIBLINGS :
case OpCodes.FROM_PARENT :
case OpCodes.OP_VARIABLE :
case OpCodes.OP_EXTFUNCTION :
case OpCodes.OP_FUNCTION :
case OpCodes.OP_GROUP :
case OpCodes.FROM_NAMESPACE :
case OpCodes.FROM_ANCESTORS :
case OpCodes.FROM_ANCESTORS_OR_SELF :
case OpCodes.MATCH_ANY_ANCESTOR :
case OpCodes.MATCH_IMMEDIATE_ANCESTOR :
case OpCodes.FROM_DESCENDANTS_OR_SELF :
case OpCodes.FROM_DESCENDANTS :
if(potentialDuplicateMakingStepCount > 0)
return false;
potentialDuplicateMakingStepCount++;
case OpCodes.FROM_ROOT :
case OpCodes.FROM_CHILDREN :
case OpCodes.FROM_SELF :
if(foundWildAttribute)
return false;
break;
default :
throw new RuntimeException(XSLMessages.createXPATHMessage(XPATHErrorResources.ER_NULL_ERROR_HANDLER, new Object[]{Integer.toString(stepType)})); //"Programmer's assertion: unknown opcode: "
// + stepType);
}
int nextStepOpCodePos = compiler.getNextStepPos(stepOpCodePos);
if (nextStepOpCodePos < 0)
break;
stepOpCodePos = nextStepOpCodePos;
}
return true;
}
public static boolean isOneStep(int analysis)
{
return (analysis & BITS_COUNT) == 0x00000001;
}
public static int getStepCount(int analysis)
{
return (analysis & BITS_COUNT);
}
First 8 bits are the number of top-level location steps. Hopefully
there will never be more that 255 location steps!!!
/**
* First 8 bits are the number of top-level location steps. Hopefully
* there will never be more that 255 location steps!!!
*/
public static final int BITS_COUNT = 0x000000FF;
4 bits are reserved for future use. /** 4 bits are reserved for future use. */
public static final int BITS_RESERVED = 0x00000F00;
Bit is on if the expression contains a top-level predicate. /** Bit is on if the expression contains a top-level predicate. */
public static final int BIT_PREDICATE = (0x00001000);
Bit is on if any of the walkers contain an ancestor step. /** Bit is on if any of the walkers contain an ancestor step. */
public static final int BIT_ANCESTOR = (0x00001000 << 1);
Bit is on if any of the walkers contain an ancestor-or-self step. /** Bit is on if any of the walkers contain an ancestor-or-self step. */
public static final int BIT_ANCESTOR_OR_SELF = (0x00001000 << 2);
Bit is on if any of the walkers contain an attribute step. /** Bit is on if any of the walkers contain an attribute step. */
public static final int BIT_ATTRIBUTE = (0x00001000 << 3);
Bit is on if any of the walkers contain a child step. /** Bit is on if any of the walkers contain a child step. */
public static final int BIT_CHILD = (0x00001000 << 4);
Bit is on if any of the walkers contain a descendant step. /** Bit is on if any of the walkers contain a descendant step. */
public static final int BIT_DESCENDANT = (0x00001000 << 5);
Bit is on if any of the walkers contain a descendant-or-self step. /** Bit is on if any of the walkers contain a descendant-or-self step. */
public static final int BIT_DESCENDANT_OR_SELF = (0x00001000 << 6);
Bit is on if any of the walkers contain a following step. /** Bit is on if any of the walkers contain a following step. */
public static final int BIT_FOLLOWING = (0x00001000 << 7);
Bit is on if any of the walkers contain a following-sibiling step. /** Bit is on if any of the walkers contain a following-sibiling step. */
public static final int BIT_FOLLOWING_SIBLING = (0x00001000 << 8);
Bit is on if any of the walkers contain a namespace step. /** Bit is on if any of the walkers contain a namespace step. */
public static final int BIT_NAMESPACE = (0x00001000 << 9);
Bit is on if any of the walkers contain a parent step. /** Bit is on if any of the walkers contain a parent step. */
public static final int BIT_PARENT = (0x00001000 << 10);
Bit is on if any of the walkers contain a preceding step. /** Bit is on if any of the walkers contain a preceding step. */
public static final int BIT_PRECEDING = (0x00001000 << 11);
Bit is on if any of the walkers contain a preceding-sibling step. /** Bit is on if any of the walkers contain a preceding-sibling step. */
public static final int BIT_PRECEDING_SIBLING = (0x00001000 << 12);
Bit is on if any of the walkers contain a self step. /** Bit is on if any of the walkers contain a self step. */
public static final int BIT_SELF = (0x00001000 << 13);
Bit is on if any of the walkers contain a filter (i.e. id(), extension
function, etc.) step.
/**
* Bit is on if any of the walkers contain a filter (i.e. id(), extension
* function, etc.) step.
*/
public static final int BIT_FILTER = (0x00001000 << 14);
Bit is on if any of the walkers contain a root step. /** Bit is on if any of the walkers contain a root step. */
public static final int BIT_ROOT = (0x00001000 << 15);
If any of these bits are on, the expression may likely traverse outside
the given subtree.
/**
* If any of these bits are on, the expression may likely traverse outside
* the given subtree.
*/
public static final int BITMASK_TRAVERSES_OUTSIDE_SUBTREE = (BIT_NAMESPACE // ??
| BIT_PRECEDING_SIBLING
| BIT_PRECEDING
| BIT_FOLLOWING_SIBLING
| BIT_FOLLOWING
| BIT_PARENT // except parent of attrs.
| BIT_ANCESTOR_OR_SELF
| BIT_ANCESTOR
| BIT_FILTER
| BIT_ROOT);
Bit is on if any of the walkers can go backwards in document
order from the context node.
/**
* Bit is on if any of the walkers can go backwards in document
* order from the context node.
*/
public static final int BIT_BACKWARDS_SELF = (0x00001000 << 16);
Found "//foo" pattern /** Found "//foo" pattern */
public static final int BIT_ANY_DESCENDANT_FROM_ROOT = (0x00001000 << 17);
Bit is on if any of the walkers contain an node() test. This is
really only useful if the count is 1.
/**
* Bit is on if any of the walkers contain an node() test. This is
* really only useful if the count is 1.
*/
public static final int BIT_NODETEST_ANY = (0x00001000 << 18);
// can't go higher than 18!
Bit is on if the expression is a match pattern. /** Bit is on if the expression is a match pattern. */
public static final int BIT_MATCH_PATTERN = (0x00001000 << 19);
}