Source/WebCore/xml/XPathStep.cpp - WebKit - Git at Google

 /*
  * Copyright (C) 2005 Frerich Raabe <raabe@kde.org>
  * Copyright (C) 2006, 2009 Apple Inc. All rights reserved.
  * Copyright (C) 2007 Alexey Proskuryakov <ap@webkit.org>
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *
  * 1. Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  * 2. Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in the
  *    documentation and/or other materials provided with the distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
  * IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
  * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
  * IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
  * NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
  * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
  * THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
  * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
  * THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include "config.h"
 #include "XPathStep.h"

 #include "Attr.h"
 #include "Document.h"
 #include "HTMLElement.h"
 #include "NodeTraversal.h"
 #include "XMLNSNames.h"
 #include "XPathParser.h"
 #include "XPathUtil.h"

 namespace WebCore {
 namespace XPath {

 Step::Step(Axis axis, NodeTest nodeTest)
     : m_axis(axis)
     , m_nodeTest(WTFMove(nodeTest))
 {
 }

 Step::Step(Axis axis, NodeTest nodeTest, Vector<std::unique_ptr<Expression>> predicates)
     : m_axis(axis)
     , m_nodeTest(WTFMove(nodeTest))
     , m_predicates(WTFMove(predicates))
 {
 }

 Step::~Step() = default;

 void Step::optimize()
 {
     // Evaluate predicates as part of node test if possible to avoid building unnecessary NodeSets.
     // E.g., there is no need to build a set of all "foo" nodes to evaluate "foo[@bar]", we can check the predicate while enumerating.
     // This optimization can be applied to predicates that are not context node list sensitive, or to first predicate that is only context position sensitive, e.g. foo[position() mod 2 = 0].
     Vector<std::unique_ptr<Expression>> remainingPredicates;
     for (auto& predicate : m_predicates) {
         if ((!predicateIsContextPositionSensitive(*predicate) || m_nodeTest.m_mergedPredicates.isEmpty()) && !predicate->isContextSizeSensitive() && remainingPredicates.isEmpty())
             m_nodeTest.m_mergedPredicates.append(WTFMove(predicate));
         else
             remainingPredicates.append(WTFMove(predicate));
     }
     m_predicates = WTFMove(remainingPredicates);
 }

 void optimizeStepPair(Step& first, Step& second, bool& dropSecondStep)
 {
     dropSecondStep = false;

     if (first.m_axis != Step::DescendantOrSelfAxis)
         return;

     if (first.m_nodeTest.m_kind != Step::NodeTest::AnyNodeTest)
         return;

     if (!first.m_predicates.isEmpty())
         return;

     if (!first.m_nodeTest.m_mergedPredicates.isEmpty())
         return;

     ASSERT(first.m_nodeTest.m_data.isEmpty());
     ASSERT(first.m_nodeTest.m_namespaceURI.isEmpty());

     // Optimize the common case of "//" AKA /descendant-or-self::node()/child::NodeTest to /descendant::NodeTest.
     if (second.m_axis != Step::ChildAxis)
         return;

     if (!second.predicatesAreContextListInsensitive())
         return;

     first.m_axis = Step::DescendantAxis;
     first.m_nodeTest = WTFMove(second.m_nodeTest);
     first.m_predicates = WTFMove(second.m_predicates);
     first.optimize();
     dropSecondStep = true;
 }

 bool Step::predicatesAreContextListInsensitive() const
 {
     for (auto& predicate : m_predicates) {
         if (predicateIsContextPositionSensitive(*predicate) || predicate->isContextSizeSensitive())
             return false;
     }

     for (auto& predicate : m_nodeTest.m_mergedPredicates) {
         if (predicateIsContextPositionSensitive(*predicate) || predicate->isContextSizeSensitive())
             return false;
     }

     return true;
 }

 void Step::evaluate(Node& context, NodeSet& nodes) const
 {
     EvaluationContext& evaluationContext = Expression::evaluationContext();
     evaluationContext.position = 0;

     nodesInAxis(context, nodes);

     // Check predicates that couldn't be merged into node test.
     for (auto& predicate : m_predicates) {
         NodeSet newNodes;
         if (!nodes.isSorted())
             newNodes.markSorted(false);

         for (unsigned j = 0; j < nodes.size(); j++) {
             Node* node = nodes[j];

             evaluationContext.node = node;
             evaluationContext.size = nodes.size();
             evaluationContext.position = j + 1;
             if (evaluatePredicate(*predicate))
                 newNodes.append(node);
         }

         nodes = WTFMove(newNodes);
     }
 }

 #if ASSERT_ENABLED
 static inline Node::NodeType primaryNodeType(Step::Axis axis)
 {
     switch (axis) {
         case Step::AttributeAxis:
             return Node::ATTRIBUTE_NODE;
         default:
             return Node::ELEMENT_NODE;
     }
 }
 #endif // ASSERT_ENABLED

 // Evaluate NodeTest without considering merged predicates.
 inline bool nodeMatchesBasicTest(Node& node, Step::Axis axis, const Step::NodeTest& nodeTest)
 {
     switch (nodeTest.m_kind) {
         case Step::NodeTest::TextNodeTest:
             return node.nodeType() == Node::TEXT_NODE || node.nodeType() == Node::CDATA_SECTION_NODE;
         case Step::NodeTest::CommentNodeTest:
             return node.nodeType() == Node::COMMENT_NODE;
         case Step::NodeTest::ProcessingInstructionNodeTest: {
             const AtomString& name = nodeTest.m_data;
             return node.nodeType() == Node::PROCESSING_INSTRUCTION_NODE && (name.isEmpty() || node.nodeName() == name);
         }
         case Step::NodeTest::AnyNodeTest:
             return true;
         case Step::NodeTest::NameTest: {
             const AtomString& name = nodeTest.m_data;
             const AtomString& namespaceURI = nodeTest.m_namespaceURI;

             if (axis == Step::AttributeAxis) {
                 ASSERT(node.isAttributeNode());

                 // In XPath land, namespace nodes are not accessible on the attribute axis.
                 if (node.namespaceURI() == XMLNSNames::xmlnsNamespaceURI)
                     return false;

                 if (name == starAtom())
                     return namespaceURI.isEmpty() || node.namespaceURI() == namespaceURI;

                 return node.localName() == name && node.namespaceURI() == namespaceURI;
             }

             // Node test on the namespace axis is not implemented yet, the caller has a check for it.
             ASSERT(axis != Step::NamespaceAxis);

             // For other axes, the principal node type is element.
             ASSERT(primaryNodeType(axis) == Node::ELEMENT_NODE);
             if (!is<Element>(node))
                 return false;

             if (name == starAtom())
                 return namespaceURI.isEmpty() || namespaceURI == node.namespaceURI();

             if (node.document().isHTMLDocument()) {
                 if (is<HTMLElement>(node)) {
                     // Paths without namespaces should match HTML elements in HTML documents despite those having an XHTML namespace. Names are compared case-insensitively.
                     return equalIgnoringASCIICase(downcast<HTMLElement>(node).localName(), name) && (namespaceURI.isNull() || namespaceURI == node.namespaceURI());
                 }
                 // An expression without any prefix shouldn't match no-namespace nodes (because HTML5 says so).
                 return downcast<Element>(node).hasLocalName(name) && namespaceURI == node.namespaceURI() && !namespaceURI.isNull();
             }
             return downcast<Element>(node).hasLocalName(name) && namespaceURI == node.namespaceURI();
         }
     }
     ASSERT_NOT_REACHED();
     return false;
 }

 inline bool nodeMatches(Node& node, Step::Axis axis, const Step::NodeTest& nodeTest)
 {
     if (!nodeMatchesBasicTest(node, axis, nodeTest))
         return false;

     EvaluationContext& evaluationContext = Expression::evaluationContext();

     // Only the first merged predicate may depend on position.
     ++evaluationContext.position;

     for (auto& predicate : nodeTest.m_mergedPredicates) {
         // No need to set context size - we only get here when evaluating predicates that do not depend on it.
         evaluationContext.node = &node;
         if (!evaluatePredicate(*predicate))
             return false;
     }

     return true;
 }

 // Result nodes are ordered in axis order. Node test (including merged predicates) is applied.
 void Step::nodesInAxis(Node& context, NodeSet& nodes) const
 {
     ASSERT(nodes.isEmpty());
     switch (m_axis) {
         case ChildAxis:
             if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
                 return;
             for (Node* node = context.firstChild(); node; node = node->nextSibling()) {
                 if (nodeMatches(*node, ChildAxis, m_nodeTest))
                     nodes.append(node);
             }
             return;
         case DescendantAxis:
             if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
                 return;
             for (Node* node = context.firstChild(); node; node = NodeTraversal::next(*node, &context)) {
                 if (nodeMatches(*node, DescendantAxis, m_nodeTest))
                     nodes.append(node);
             }
             return;
         case ParentAxis:
             if (context.isAttributeNode()) {
                 Element* node = static_cast<Attr&>(context).ownerElement();
                 if (nodeMatches(*node, ParentAxis, m_nodeTest))
                     nodes.append(node);
             } else {
                 ContainerNode* node = context.parentNode();
                 if (node && nodeMatches(*node, ParentAxis, m_nodeTest))
                     nodes.append(node);
             }
             return;
         case AncestorAxis: {
             Node* node = &context;
             if (context.isAttributeNode()) {
                 node = static_cast<Attr&>(context).ownerElement();
                 if (nodeMatches(*node, AncestorAxis, m_nodeTest))
                     nodes.append(node);
             }
             for (node = node->parentNode(); node; node = node->parentNode()) {
                 if (nodeMatches(*node, AncestorAxis, m_nodeTest))
                     nodes.append(node);
             }
             nodes.markSorted(false);
             return;
         }
         case FollowingSiblingAxis:
             if (context.isAttributeNode())
                 return;
             for (Node* node = context.nextSibling(); node; node = node->nextSibling()) {
                 if (nodeMatches(*node, FollowingSiblingAxis, m_nodeTest))
                     nodes.append(node);
             }
             return;
         case PrecedingSiblingAxis:
             if (context.isAttributeNode())
                 return;
             for (Node* node = context.previousSibling(); node; node = node->previousSibling()) {
                 if (nodeMatches(*node, PrecedingSiblingAxis, m_nodeTest))
                     nodes.append(node);
             }
             nodes.markSorted(false);
             return;
         case FollowingAxis:
             if (context.isAttributeNode()) {
                 Node* node = static_cast<Attr&>(context).ownerElement();
                 while ((node = NodeTraversal::next(*node))) {
                     if (nodeMatches(*node, FollowingAxis, m_nodeTest))
                         nodes.append(node);
                 }
             } else {
                 for (Node* parent = &context; !isRootDomNode(parent); parent = parent->parentNode()) {
                     for (Node* node = parent->nextSibling(); node; node = node->nextSibling()) {
                         if (nodeMatches(*node, FollowingAxis, m_nodeTest))
                             nodes.append(node);
                         for (Node* child = node->firstChild(); child; child = NodeTraversal::next(*child, node)) {
                             if (nodeMatches(*child, FollowingAxis, m_nodeTest))
                                 nodes.append(child);
                         }
                     }
                 }
             }
             return;
         case PrecedingAxis: {
             Node* node;
             if (context.isAttributeNode())
                 node = static_cast<Attr&>(context).ownerElement();
             else
                 node = &context;
             while (ContainerNode* parent = node->parentNode()) {
                 for (node = NodeTraversal::previous(*node); node != parent; node = NodeTraversal::previous(*node)) {
                     if (nodeMatches(*node, PrecedingAxis, m_nodeTest))
                         nodes.append(node);
                 }
                 node = parent;
             }
             nodes.markSorted(false);
             return;
         }
         case AttributeAxis: {
             if (!is<Element>(context))
                 return;

             Element& contextElement = downcast<Element>(context);

             // Avoid lazily creating attribute nodes for attributes that we do not need anyway.
             if (m_nodeTest.m_kind == NodeTest::NameTest && m_nodeTest.m_data != starAtom()) {
                 auto attr = contextElement.getAttributeNodeNS(m_nodeTest.m_namespaceURI, m_nodeTest.m_data);
                 if (attr && attr->namespaceURI() != XMLNSNames::xmlnsNamespaceURI) { // In XPath land, namespace nodes are not accessible on the attribute axis.
                     if (nodeMatches(*attr, AttributeAxis, m_nodeTest)) // Still need to check merged predicates.
                         nodes.append(WTFMove(attr));
                 }
                 return;
             }

             if (!contextElement.hasAttributes())
                 return;

             for (const Attribute& attribute : contextElement.attributesIterator()) {
                 auto attr = contextElement.ensureAttr(attribute.name());
                 if (nodeMatches(attr.get(), AttributeAxis, m_nodeTest))
                     nodes.append(WTFMove(attr));
             }
             return;
         }
         case NamespaceAxis:
             // XPath namespace nodes are not implemented yet.
             return;
         case SelfAxis:
             if (nodeMatches(context, SelfAxis, m_nodeTest))
                 nodes.append(&context);
             return;
         case DescendantOrSelfAxis:
             if (nodeMatches(context, DescendantOrSelfAxis, m_nodeTest))
                 nodes.append(&context);
             if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
                 return;
             for (Node* node = context.firstChild(); node; node = NodeTraversal::next(*node, &context)) {
                 if (nodeMatches(*node, DescendantOrSelfAxis, m_nodeTest))
                     nodes.append(node);
             }
             return;
         case AncestorOrSelfAxis: {
             if (nodeMatches(context, AncestorOrSelfAxis, m_nodeTest))
                 nodes.append(&context);
             Node* node = &context;
             if (context.isAttributeNode()) {
                 node = static_cast<Attr&>(context).ownerElement();
                 if (nodeMatches(*node, AncestorOrSelfAxis, m_nodeTest))
                     nodes.append(node);
             }
             for (node = node->parentNode(); node; node = node->parentNode()) {
                 if (nodeMatches(*node, AncestorOrSelfAxis, m_nodeTest))
                     nodes.append(node);
             }
             nodes.markSorted(false);
             return;
         }
     }
     ASSERT_NOT_REACHED();
 }

 }
 }
	/*
	* Copyright (C) 2005 Frerich Raabe <raabe@kde.org>
	* Copyright (C) 2006, 2009 Apple Inc. All rights reserved.
	* Copyright (C) 2007 Alexey Proskuryakov <ap@webkit.org>
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	*
	* 1. Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* 2. Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in the
	* documentation and/or other materials provided with the distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE AUTHOR ``AS IS'' AND ANY EXPRESS OR
	* IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES
	* OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.
	* IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT
	* NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
	* DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
	* THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
	* (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF
	* THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include "config.h"
	#include "XPathStep.h"

	#include "Attr.h"
	#include "Document.h"
	#include "HTMLElement.h"
	#include "NodeTraversal.h"
	#include "XMLNSNames.h"
	#include "XPathParser.h"
	#include "XPathUtil.h"

	namespace WebCore {
	namespace XPath {

	Step::Step(Axis axis, NodeTest nodeTest)
	: m_axis(axis)
	, m_nodeTest(WTFMove(nodeTest))
	{
	}

	Step::Step(Axis axis, NodeTest nodeTest, Vector<std::unique_ptr<Expression>> predicates)
	: m_axis(axis)
	, m_nodeTest(WTFMove(nodeTest))
	, m_predicates(WTFMove(predicates))
	{
	}

	Step::~Step() = default;

	void Step::optimize()
	{
	// Evaluate predicates as part of node test if possible to avoid building unnecessary NodeSets.
	// E.g., there is no need to build a set of all "foo" nodes to evaluate "foo[@bar]", we can check the predicate while enumerating.
	// This optimization can be applied to predicates that are not context node list sensitive, or to first predicate that is only context position sensitive, e.g. foo[position() mod 2 = 0].
	Vector<std::unique_ptr<Expression>> remainingPredicates;
	for (auto& predicate : m_predicates) {
	if ((!predicateIsContextPositionSensitive(*predicate) \|\| m_nodeTest.m_mergedPredicates.isEmpty()) && !predicate->isContextSizeSensitive() && remainingPredicates.isEmpty())
	m_nodeTest.m_mergedPredicates.append(WTFMove(predicate));
	else
	remainingPredicates.append(WTFMove(predicate));
	}
	m_predicates = WTFMove(remainingPredicates);
	}

	void optimizeStepPair(Step& first, Step& second, bool& dropSecondStep)
	{
	dropSecondStep = false;

	if (first.m_axis != Step::DescendantOrSelfAxis)
	return;

	if (first.m_nodeTest.m_kind != Step::NodeTest::AnyNodeTest)
	return;

	if (!first.m_predicates.isEmpty())
	return;

	if (!first.m_nodeTest.m_mergedPredicates.isEmpty())
	return;

	ASSERT(first.m_nodeTest.m_data.isEmpty());
	ASSERT(first.m_nodeTest.m_namespaceURI.isEmpty());

	// Optimize the common case of "//" AKA /descendant-or-self::node()/child::NodeTest to /descendant::NodeTest.
	if (second.m_axis != Step::ChildAxis)
	return;

	if (!second.predicatesAreContextListInsensitive())
	return;

	first.m_axis = Step::DescendantAxis;
	first.m_nodeTest = WTFMove(second.m_nodeTest);
	first.m_predicates = WTFMove(second.m_predicates);
	first.optimize();
	dropSecondStep = true;
	}

	bool Step::predicatesAreContextListInsensitive() const
	{
	for (auto& predicate : m_predicates) {
	if (predicateIsContextPositionSensitive(*predicate) \|\| predicate->isContextSizeSensitive())
	return false;
	}

	for (auto& predicate : m_nodeTest.m_mergedPredicates) {
	if (predicateIsContextPositionSensitive(*predicate) \|\| predicate->isContextSizeSensitive())
	return false;
	}

	return true;
	}

	void Step::evaluate(Node& context, NodeSet& nodes) const
	{
	EvaluationContext& evaluationContext = Expression::evaluationContext();
	evaluationContext.position = 0;

	nodesInAxis(context, nodes);

	// Check predicates that couldn't be merged into node test.
	for (auto& predicate : m_predicates) {
	NodeSet newNodes;
	if (!nodes.isSorted())
	newNodes.markSorted(false);

	for (unsigned j = 0; j < nodes.size(); j++) {
	Node* node = nodes[j];

	evaluationContext.node = node;
	evaluationContext.size = nodes.size();
	evaluationContext.position = j + 1;
	if (evaluatePredicate(*predicate))
	newNodes.append(node);
	}

	nodes = WTFMove(newNodes);
	}
	}

	#if ASSERT_ENABLED
	static inline Node::NodeType primaryNodeType(Step::Axis axis)
	{
	switch (axis) {
	case Step::AttributeAxis:
	return Node::ATTRIBUTE_NODE;
	default:
	return Node::ELEMENT_NODE;
	}
	}
	#endif // ASSERT_ENABLED

	// Evaluate NodeTest without considering merged predicates.
	inline bool nodeMatchesBasicTest(Node& node, Step::Axis axis, const Step::NodeTest& nodeTest)
	{
	switch (nodeTest.m_kind) {
	case Step::NodeTest::TextNodeTest:
	return node.nodeType() == Node::TEXT_NODE \|\| node.nodeType() == Node::CDATA_SECTION_NODE;
	case Step::NodeTest::CommentNodeTest:
	return node.nodeType() == Node::COMMENT_NODE;
	case Step::NodeTest::ProcessingInstructionNodeTest: {
	const AtomString& name = nodeTest.m_data;
	return node.nodeType() == Node::PROCESSING_INSTRUCTION_NODE && (name.isEmpty() \|\| node.nodeName() == name);
	}
	case Step::NodeTest::AnyNodeTest:
	return true;
	case Step::NodeTest::NameTest: {
	const AtomString& name = nodeTest.m_data;
	const AtomString& namespaceURI = nodeTest.m_namespaceURI;

	if (axis == Step::AttributeAxis) {
	ASSERT(node.isAttributeNode());

	// In XPath land, namespace nodes are not accessible on the attribute axis.
	if (node.namespaceURI() == XMLNSNames::xmlnsNamespaceURI)
	return false;

	if (name == starAtom())
	return namespaceURI.isEmpty() \|\| node.namespaceURI() == namespaceURI;

	return node.localName() == name && node.namespaceURI() == namespaceURI;
	}

	// Node test on the namespace axis is not implemented yet, the caller has a check for it.
	ASSERT(axis != Step::NamespaceAxis);

	// For other axes, the principal node type is element.
	ASSERT(primaryNodeType(axis) == Node::ELEMENT_NODE);
	if (!is<Element>(node))
	return false;

	if (name == starAtom())
	return namespaceURI.isEmpty() \|\| namespaceURI == node.namespaceURI();

	if (node.document().isHTMLDocument()) {
	if (is<HTMLElement>(node)) {
	// Paths without namespaces should match HTML elements in HTML documents despite those having an XHTML namespace. Names are compared case-insensitively.
	return equalIgnoringASCIICase(downcast<HTMLElement>(node).localName(), name) && (namespaceURI.isNull() \|\| namespaceURI == node.namespaceURI());
	}
	// An expression without any prefix shouldn't match no-namespace nodes (because HTML5 says so).
	return downcast<Element>(node).hasLocalName(name) && namespaceURI == node.namespaceURI() && !namespaceURI.isNull();
	}
	return downcast<Element>(node).hasLocalName(name) && namespaceURI == node.namespaceURI();
	}
	}
	ASSERT_NOT_REACHED();
	return false;
	}

	inline bool nodeMatches(Node& node, Step::Axis axis, const Step::NodeTest& nodeTest)
	{
	if (!nodeMatchesBasicTest(node, axis, nodeTest))
	return false;

	EvaluationContext& evaluationContext = Expression::evaluationContext();

	// Only the first merged predicate may depend on position.
	++evaluationContext.position;

	for (auto& predicate : nodeTest.m_mergedPredicates) {
	// No need to set context size - we only get here when evaluating predicates that do not depend on it.
	evaluationContext.node = &node;
	if (!evaluatePredicate(*predicate))
	return false;
	}

	return true;
	}

	// Result nodes are ordered in axis order. Node test (including merged predicates) is applied.
	void Step::nodesInAxis(Node& context, NodeSet& nodes) const
	{
	ASSERT(nodes.isEmpty());
	switch (m_axis) {
	case ChildAxis:
	if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
	return;
	for (Node* node = context.firstChild(); node; node = node->nextSibling()) {
	if (nodeMatches(*node, ChildAxis, m_nodeTest))
	nodes.append(node);
	}
	return;
	case DescendantAxis:
	if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
	return;
	for (Node* node = context.firstChild(); node; node = NodeTraversal::next(*node, &context)) {
	if (nodeMatches(*node, DescendantAxis, m_nodeTest))
	nodes.append(node);
	}
	return;
	case ParentAxis:
	if (context.isAttributeNode()) {
	Element* node = static_cast<Attr&>(context).ownerElement();
	if (nodeMatches(*node, ParentAxis, m_nodeTest))
	nodes.append(node);
	} else {
	ContainerNode* node = context.parentNode();
	if (node && nodeMatches(*node, ParentAxis, m_nodeTest))
	nodes.append(node);
	}
	return;
	case AncestorAxis: {
	Node* node = &context;
	if (context.isAttributeNode()) {
	node = static_cast<Attr&>(context).ownerElement();
	if (nodeMatches(*node, AncestorAxis, m_nodeTest))
	nodes.append(node);
	}
	for (node = node->parentNode(); node; node = node->parentNode()) {
	if (nodeMatches(*node, AncestorAxis, m_nodeTest))
	nodes.append(node);
	}
	nodes.markSorted(false);
	return;
	}
	case FollowingSiblingAxis:
	if (context.isAttributeNode())
	return;
	for (Node* node = context.nextSibling(); node; node = node->nextSibling()) {
	if (nodeMatches(*node, FollowingSiblingAxis, m_nodeTest))
	nodes.append(node);
	}
	return;
	case PrecedingSiblingAxis:
	if (context.isAttributeNode())
	return;
	for (Node* node = context.previousSibling(); node; node = node->previousSibling()) {
	if (nodeMatches(*node, PrecedingSiblingAxis, m_nodeTest))
	nodes.append(node);
	}
	nodes.markSorted(false);
	return;
	case FollowingAxis:
	if (context.isAttributeNode()) {
	Node* node = static_cast<Attr&>(context).ownerElement();
	while ((node = NodeTraversal::next(*node))) {
	if (nodeMatches(*node, FollowingAxis, m_nodeTest))
	nodes.append(node);
	}
	} else {
	for (Node* parent = &context; !isRootDomNode(parent); parent = parent->parentNode()) {
	for (Node* node = parent->nextSibling(); node; node = node->nextSibling()) {
	if (nodeMatches(*node, FollowingAxis, m_nodeTest))
	nodes.append(node);
	for (Node* child = node->firstChild(); child; child = NodeTraversal::next(*child, node)) {
	if (nodeMatches(*child, FollowingAxis, m_nodeTest))
	nodes.append(child);
	}
	}
	}
	}
	return;
	case PrecedingAxis: {
	Node* node;
	if (context.isAttributeNode())
	node = static_cast<Attr&>(context).ownerElement();
	else
	node = &context;
	while (ContainerNode* parent = node->parentNode()) {
	for (node = NodeTraversal::previous(node); node != parent; node = NodeTraversal::previous(node)) {
	if (nodeMatches(*node, PrecedingAxis, m_nodeTest))
	nodes.append(node);
	}
	node = parent;
	}
	nodes.markSorted(false);
	return;
	}
	case AttributeAxis: {
	if (!is<Element>(context))
	return;

	Element& contextElement = downcast<Element>(context);

	// Avoid lazily creating attribute nodes for attributes that we do not need anyway.
	if (m_nodeTest.m_kind == NodeTest::NameTest && m_nodeTest.m_data != starAtom()) {
	auto attr = contextElement.getAttributeNodeNS(m_nodeTest.m_namespaceURI, m_nodeTest.m_data);
	if (attr && attr->namespaceURI() != XMLNSNames::xmlnsNamespaceURI) { // In XPath land, namespace nodes are not accessible on the attribute axis.
	if (nodeMatches(*attr, AttributeAxis, m_nodeTest)) // Still need to check merged predicates.
	nodes.append(WTFMove(attr));
	}
	return;
	}

	if (!contextElement.hasAttributes())
	return;

	for (const Attribute& attribute : contextElement.attributesIterator()) {
	auto attr = contextElement.ensureAttr(attribute.name());
	if (nodeMatches(attr.get(), AttributeAxis, m_nodeTest))
	nodes.append(WTFMove(attr));
	}
	return;
	}
	case NamespaceAxis:
	// XPath namespace nodes are not implemented yet.
	return;
	case SelfAxis:
	if (nodeMatches(context, SelfAxis, m_nodeTest))
	nodes.append(&context);
	return;
	case DescendantOrSelfAxis:
	if (nodeMatches(context, DescendantOrSelfAxis, m_nodeTest))
	nodes.append(&context);
	if (context.isAttributeNode()) // In XPath model, attribute nodes do not have children.
	return;
	for (Node* node = context.firstChild(); node; node = NodeTraversal::next(*node, &context)) {
	if (nodeMatches(*node, DescendantOrSelfAxis, m_nodeTest))
	nodes.append(node);
	}
	return;
	case AncestorOrSelfAxis: {
	if (nodeMatches(context, AncestorOrSelfAxis, m_nodeTest))
	nodes.append(&context);
	Node* node = &context;
	if (context.isAttributeNode()) {
	node = static_cast<Attr&>(context).ownerElement();
	if (nodeMatches(*node, AncestorOrSelfAxis, m_nodeTest))
	nodes.append(node);
	}
	for (node = node->parentNode(); node; node = node->parentNode()) {
	if (nodeMatches(*node, AncestorOrSelfAxis, m_nodeTest))
	nodes.append(node);
	}
	nodes.markSorted(false);
	return;
	}
	}
	ASSERT_NOT_REACHED();
	}

	}
	}