gecko-dev/dom/xul/templates/nsRuleNetwork.h

862 строки
28 KiB
C++

/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */
/* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this
* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
/*
A rule discrimination network implementation based on ideas from
RETE and TREAT.
RETE is described in Charles Forgy, "Rete: A Fast Algorithm for the
Many Patterns/Many Objects Match Problem", Artificial Intelligence
19(1): pp. 17-37, 1982.
TREAT is described in Daniel P. Miranker, "TREAT: A Better Match
Algorithm for AI Production System Matching", AAAI 1987: pp. 42-47.
--
TO DO:
. nsAssignmentSet::List objects are allocated by the gallon. We
should make it so that these are always allocated from a pool,
maybe owned by the nsRuleNetwork?
*/
#ifndef nsRuleNetwork_h__
#define nsRuleNetwork_h__
#include "mozilla/Attributes.h"
#include "nsCOMPtr.h"
#include "nsCOMArray.h"
#include "nsIAtom.h"
#include "nsIDOMNode.h"
#include "plhash.h"
#include "pldhash.h"
#include "nsIRDFNode.h"
class nsXULTemplateResultSetRDF;
//----------------------------------------------------------------------
/**
* A memory element that supports an instantiation. A memory element holds a
* set of nodes involved in an RDF test such as <member> or <triple> test. A
* memory element is created when a specific test matches. The query processor
* maintains a map between the memory elements and the results they eventually
* matched. When an assertion is removed from the graph, this map is consulted
* to determine which results will no longer match.
*/
class MemoryElement {
protected:
MemoryElement() { MOZ_COUNT_CTOR(MemoryElement); }
public:
virtual ~MemoryElement() { MOZ_COUNT_DTOR(MemoryElement); }
virtual const char* Type() const = 0;
virtual PLHashNumber Hash() const = 0;
virtual bool Equals(const MemoryElement& aElement) const = 0;
bool operator==(const MemoryElement& aMemoryElement) const {
return Equals(aMemoryElement);
}
bool operator!=(const MemoryElement& aMemoryElement) const {
return !Equals(aMemoryElement);
}
};
//----------------------------------------------------------------------
/**
* A collection of memory elements
*/
class MemoryElementSet {
public:
class ConstIterator;
friend class ConstIterator;
protected:
class List {
public:
List() { MOZ_COUNT_CTOR(MemoryElementSet::List); }
protected:
~List() {
MOZ_COUNT_DTOR(MemoryElementSet::List);
delete mElement;
NS_IF_RELEASE(mNext); }
public:
int32_t AddRef() { return ++mRefCnt; }
int32_t Release() {
int32_t refcnt = --mRefCnt;
if (refcnt == 0) delete this;
return refcnt; }
MemoryElement* mElement;
int32_t mRefCnt;
List* mNext;
};
List* mElements;
public:
MemoryElementSet() : mElements(nullptr) {
MOZ_COUNT_CTOR(MemoryElementSet); }
MemoryElementSet(const MemoryElementSet& aSet) : mElements(aSet.mElements) {
MOZ_COUNT_CTOR(MemoryElementSet);
NS_IF_ADDREF(mElements); }
MemoryElementSet& operator=(const MemoryElementSet& aSet) {
NS_IF_RELEASE(mElements);
mElements = aSet.mElements;
NS_IF_ADDREF(mElements);
return *this; }
~MemoryElementSet() {
MOZ_COUNT_DTOR(MemoryElementSet);
NS_IF_RELEASE(mElements); }
public:
class ConstIterator {
public:
explicit ConstIterator(List* aElementList) : mCurrent(aElementList) {
NS_IF_ADDREF(mCurrent); }
ConstIterator(const ConstIterator& aConstIterator)
: mCurrent(aConstIterator.mCurrent) {
NS_IF_ADDREF(mCurrent); }
ConstIterator& operator=(const ConstIterator& aConstIterator) {
NS_IF_RELEASE(mCurrent);
mCurrent = aConstIterator.mCurrent;
NS_IF_ADDREF(mCurrent);
return *this; }
~ConstIterator() { NS_IF_RELEASE(mCurrent); }
ConstIterator& operator++() {
List* next = mCurrent->mNext;
NS_RELEASE(mCurrent);
mCurrent = next;
NS_IF_ADDREF(mCurrent);
return *this; }
ConstIterator operator++(int) {
ConstIterator result(*this);
List* next = mCurrent->mNext;
NS_RELEASE(mCurrent);
mCurrent = next;
NS_IF_ADDREF(mCurrent);
return result; }
const MemoryElement& operator*() const {
return *mCurrent->mElement; }
const MemoryElement* operator->() const {
return mCurrent->mElement; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
protected:
List* mCurrent;
};
ConstIterator First() const { return ConstIterator(mElements); }
ConstIterator Last() const { return ConstIterator(nullptr); }
// N.B. that the set assumes ownership of the element
nsresult Add(MemoryElement* aElement);
};
//----------------------------------------------------------------------
/**
* An assignment of a value to a variable
*/
class nsAssignment {
public:
const nsCOMPtr<nsIAtom> mVariable;
nsCOMPtr<nsIRDFNode> mValue;
nsAssignment(nsIAtom* aVariable, nsIRDFNode* aValue)
: mVariable(aVariable),
mValue(aValue)
{ MOZ_COUNT_CTOR(nsAssignment); }
nsAssignment(const nsAssignment& aAssignment)
: mVariable(aAssignment.mVariable),
mValue(aAssignment.mValue)
{ MOZ_COUNT_CTOR(nsAssignment); }
~nsAssignment() { MOZ_COUNT_DTOR(nsAssignment); }
bool operator==(const nsAssignment& aAssignment) const {
return mVariable == aAssignment.mVariable && mValue == aAssignment.mValue; }
bool operator!=(const nsAssignment& aAssignment) const {
return mVariable != aAssignment.mVariable || mValue != aAssignment.mValue; }
PLHashNumber Hash() const {
// XXX I have no idea if this hashing function is good or not // XXX change this
PLHashNumber temp = PLHashNumber(NS_PTR_TO_INT32(mValue.get())) >> 2; // strip alignment bits
return (temp & 0xffff) | NS_PTR_TO_INT32(mVariable.get()); }
};
//----------------------------------------------------------------------
/**
* A collection of value-to-variable assignments that minimizes
* copying by sharing subsets when possible.
*/
class nsAssignmentSet {
public:
class ConstIterator;
friend class ConstIterator;
protected:
class List {
public:
explicit List(const nsAssignment& aAssignment) : mAssignment(aAssignment) {
MOZ_COUNT_CTOR(nsAssignmentSet::List); }
protected:
~List() {
MOZ_COUNT_DTOR(nsAssignmentSet::List);
NS_IF_RELEASE(mNext); }
public:
int32_t AddRef() { return ++mRefCnt; }
int32_t Release() {
int32_t refcnt = --mRefCnt;
if (refcnt == 0) delete this;
return refcnt; }
nsAssignment mAssignment;
int32_t mRefCnt;
List* mNext;
};
List* mAssignments;
public:
nsAssignmentSet()
: mAssignments(nullptr)
{ MOZ_COUNT_CTOR(nsAssignmentSet); }
nsAssignmentSet(const nsAssignmentSet& aSet)
: mAssignments(aSet.mAssignments) {
MOZ_COUNT_CTOR(nsAssignmentSet);
NS_IF_ADDREF(mAssignments); }
nsAssignmentSet& operator=(const nsAssignmentSet& aSet) {
NS_IF_RELEASE(mAssignments);
mAssignments = aSet.mAssignments;
NS_IF_ADDREF(mAssignments);
return *this; }
~nsAssignmentSet() {
MOZ_COUNT_DTOR(nsAssignmentSet);
NS_IF_RELEASE(mAssignments); }
public:
class ConstIterator {
public:
explicit ConstIterator(List* aAssignmentList) : mCurrent(aAssignmentList) {
NS_IF_ADDREF(mCurrent); }
ConstIterator(const ConstIterator& aConstIterator)
: mCurrent(aConstIterator.mCurrent) {
NS_IF_ADDREF(mCurrent); }
ConstIterator& operator=(const ConstIterator& aConstIterator) {
NS_IF_RELEASE(mCurrent);
mCurrent = aConstIterator.mCurrent;
NS_IF_ADDREF(mCurrent);
return *this; }
~ConstIterator() { NS_IF_RELEASE(mCurrent); }
ConstIterator& operator++() {
List* next = mCurrent->mNext;
NS_RELEASE(mCurrent);
mCurrent = next;
NS_IF_ADDREF(mCurrent);
return *this; }
ConstIterator operator++(int) {
ConstIterator result(*this);
List* next = mCurrent->mNext;
NS_RELEASE(mCurrent);
mCurrent = next;
NS_IF_ADDREF(mCurrent);
return result; }
const nsAssignment& operator*() const {
return mCurrent->mAssignment; }
const nsAssignment* operator->() const {
return &mCurrent->mAssignment; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
protected:
List* mCurrent;
};
ConstIterator First() const { return ConstIterator(mAssignments); }
ConstIterator Last() const { return ConstIterator(nullptr); }
public:
/**
* Add an assignment to the set
* @param aElement the assigment to add
* @return NS_OK if all is well, NS_ERROR_OUT_OF_MEMORY if memory
* could not be allocated for the addition.
*/
nsresult Add(const nsAssignment& aElement);
/**
* Determine if the assignment set contains the specified variable
* to value assignment.
* @param aVariable the variable for which to lookup the binding
* @param aValue the value to query
* @return true if aVariable is bound to aValue; false otherwise.
*/
bool HasAssignment(nsIAtom* aVariable, nsIRDFNode* aValue) const;
/**
* Determine if the assignment set contains the specified assignment
* @param aAssignment the assignment to search for
* @return true if the set contains the assignment, false otherwise.
*/
bool HasAssignment(const nsAssignment& aAssignment) const {
return HasAssignment(aAssignment.mVariable, aAssignment.mValue); }
/**
* Determine whether the assignment set has an assignment for the
* specified variable.
* @param aVariable the variable to query
* @return true if the assignment set has an assignment for the variable,
* false otherwise.
*/
bool HasAssignmentFor(nsIAtom* aVariable) const;
/**
* Retrieve the assignment for the specified variable
* @param aVariable the variable to query
* @param aValue an out parameter that will receive the value assigned
* to the variable, if any.
* @return true if the variable has an assignment, false
* if there was no assignment for the variable.
*/
bool GetAssignmentFor(nsIAtom* aVariable, nsIRDFNode** aValue) const;
/**
* Count the number of assignments in the set
* @return the number of assignments in the set
*/
int32_t Count() const;
/**
* Determine if the set is empty
* @return true if the assignment set is empty, false otherwise.
*/
bool IsEmpty() const { return mAssignments == nullptr; }
bool Equals(const nsAssignmentSet& aSet) const;
bool operator==(const nsAssignmentSet& aSet) const { return Equals(aSet); }
bool operator!=(const nsAssignmentSet& aSet) const { return !Equals(aSet); }
};
//----------------------------------------------------------------------
/**
* A collection of variable-to-value bindings, with the memory elements
* that support those bindings. Essentially, an instantiation is the
* collection of variables and values assigned to those variables for a single
* result. For each RDF rule in the rule network, each instantiation is
* examined and either extended with additional bindings specified by the RDF
* rule, or removed if the rule doesn't apply (for instance if a node has no
* children). When an instantiation gets to the last node of the rule network,
* which is always an nsInstantiationNode, a result is created for it.
*
* An instantiation object is typically created by "extending" another
* instantiation object. That is, using the copy constructor, and
* adding bindings and support to the instantiation.
*/
class Instantiation
{
public:
/**
* The variable-to-value bindings
*/
nsAssignmentSet mAssignments;
/**
* The memory elements that support the bindings.
*/
MemoryElementSet mSupport;
Instantiation() { MOZ_COUNT_CTOR(Instantiation); }
Instantiation(const Instantiation& aInstantiation)
: mAssignments(aInstantiation.mAssignments),
mSupport(aInstantiation.mSupport) {
MOZ_COUNT_CTOR(Instantiation); }
Instantiation& operator=(const Instantiation& aInstantiation) {
mAssignments = aInstantiation.mAssignments;
mSupport = aInstantiation.mSupport;
return *this; }
~Instantiation() { MOZ_COUNT_DTOR(Instantiation); }
/**
* Add the specified variable-to-value assignment to the instantiation's
* set of assignments.
* @param aVariable the variable to which is being assigned
* @param aValue the value that is being assigned
* @return NS_OK if no errors, NS_ERROR_OUT_OF_MEMORY if there
* is not enough memory to perform the operation
*/
nsresult AddAssignment(nsIAtom* aVariable, nsIRDFNode* aValue) {
mAssignments.Add(nsAssignment(aVariable, aValue));
return NS_OK; }
/**
* Add a memory element to the set of memory elements that are
* supporting the instantiation
* @param aMemoryElement the memory element to add to the
* instantiation's set of support
* @return NS_OK if no errors occurred, NS_ERROR_OUT_OF_MEMORY
* if there is not enough memory to perform the operation.
*/
nsresult AddSupportingElement(MemoryElement* aMemoryElement) {
mSupport.Add(aMemoryElement);
return NS_OK; }
bool Equals(const Instantiation& aInstantiation) const {
return mAssignments == aInstantiation.mAssignments; }
bool operator==(const Instantiation& aInstantiation) const {
return Equals(aInstantiation); }
bool operator!=(const Instantiation& aInstantiation) const {
return !Equals(aInstantiation); }
static PLHashNumber Hash(const void* aKey);
static int Compare(const void* aLeft, const void* aRight);
};
//----------------------------------------------------------------------
/**
* A collection of intantiations
*/
class InstantiationSet
{
public:
InstantiationSet();
InstantiationSet(const InstantiationSet& aInstantiationSet);
InstantiationSet& operator=(const InstantiationSet& aInstantiationSet);
~InstantiationSet() {
MOZ_COUNT_DTOR(InstantiationSet);
Clear(); }
class ConstIterator;
friend class ConstIterator;
class Iterator;
friend class Iterator;
friend class nsXULTemplateResultSetRDF; // so it can get to the List
protected:
class List {
public:
Instantiation mInstantiation;
List* mNext;
List* mPrev;
List() { MOZ_COUNT_CTOR(InstantiationSet::List); }
~List() { MOZ_COUNT_DTOR(InstantiationSet::List); }
};
List mHead;
public:
class ConstIterator {
protected:
friend class Iterator; // XXXwaterson so broken.
List* mCurrent;
public:
explicit ConstIterator(List* aList) : mCurrent(aList) {}
ConstIterator(const ConstIterator& aConstIterator)
: mCurrent(aConstIterator.mCurrent) {}
ConstIterator& operator=(const ConstIterator& aConstIterator) {
mCurrent = aConstIterator.mCurrent;
return *this; }
ConstIterator& operator++() {
mCurrent = mCurrent->mNext;
return *this; }
ConstIterator operator++(int) {
ConstIterator result(*this);
mCurrent = mCurrent->mNext;
return result; }
ConstIterator& operator--() {
mCurrent = mCurrent->mPrev;
return *this; }
ConstIterator operator--(int) {
ConstIterator result(*this);
mCurrent = mCurrent->mPrev;
return result; }
const Instantiation& operator*() const {
return mCurrent->mInstantiation; }
const Instantiation* operator->() const {
return &mCurrent->mInstantiation; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
};
ConstIterator First() const { return ConstIterator(mHead.mNext); }
ConstIterator Last() const { return ConstIterator(const_cast<List*>(&mHead)); }
class Iterator : public ConstIterator {
public:
explicit Iterator(List* aList) : ConstIterator(aList) {}
Iterator& operator++() {
mCurrent = mCurrent->mNext;
return *this; }
Iterator operator++(int) {
Iterator result(*this);
mCurrent = mCurrent->mNext;
return result; }
Iterator& operator--() {
mCurrent = mCurrent->mPrev;
return *this; }
Iterator operator--(int) {
Iterator result(*this);
mCurrent = mCurrent->mPrev;
return result; }
Instantiation& operator*() const {
return mCurrent->mInstantiation; }
Instantiation* operator->() const {
return &mCurrent->mInstantiation; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
friend class InstantiationSet;
};
Iterator First() { return Iterator(mHead.mNext); }
Iterator Last() { return Iterator(&mHead); }
bool Empty() const { return First() == Last(); }
Iterator Append(const Instantiation& aInstantiation) {
return Insert(Last(), aInstantiation); }
Iterator Insert(Iterator aBefore, const Instantiation& aInstantiation);
Iterator Erase(Iterator aElement);
void Clear();
bool HasAssignmentFor(nsIAtom* aVariable) const;
};
//----------------------------------------------------------------------
/**
* A abstract base class for all nodes in the rule network
*/
class ReteNode
{
public:
ReteNode() {}
virtual ~ReteNode() {}
/**
* Propagate a set of instantiations "down" through the
* network. Each instantiation is a partial set of
* variable-to-value assignments, along with the memory elements
* that support it.
*
* The node must evaluate each instantiation, and either 1)
* extend it with additional assignments and memory-element
* support, or 2) remove it from the set because it is
* inconsistent with the constraints that this node applies.
*
* The node must then pass the resulting instantiation set along
* to any of its children in the network. (In other words, the
* node must recursively call Propagate() on its children. We
* should fix this to make the algorithm interruptable.)
*
* See TestNode::Propagate for details about instantiation set ownership
*
* @param aInstantiations the set of instantiations to propagate
* down through the network.
* @param aIsUpdate true if updating, false for first generation
* @param aTakenInstantiations true if the ownership over aInstantiations
* has been taken from the caller. If false,
* the caller owns it.
* @return NS_OK if no errors occurred.
*/
virtual nsresult Propagate(InstantiationSet& aInstantiations,
bool aIsUpdate, bool& aTakenInstantiations) = 0;
};
//----------------------------------------------------------------------
/**
* A collection of nodes in the rule network
*/
class ReteNodeSet
{
public:
ReteNodeSet();
~ReteNodeSet();
nsresult Add(ReteNode* aNode);
nsresult Clear();
class Iterator;
class ConstIterator {
public:
explicit ConstIterator(ReteNode** aNode) : mCurrent(aNode) {}
ConstIterator(const ConstIterator& aConstIterator)
: mCurrent(aConstIterator.mCurrent) {}
ConstIterator& operator=(const ConstIterator& aConstIterator) {
mCurrent = aConstIterator.mCurrent;
return *this; }
ConstIterator& operator++() {
++mCurrent;
return *this; }
ConstIterator operator++(int) {
ConstIterator result(*this);
++mCurrent;
return result; }
const ReteNode* operator*() const {
return *mCurrent; }
const ReteNode* operator->() const {
return *mCurrent; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
protected:
friend class Iterator; // XXXwaterson this is so wrong!
ReteNode** mCurrent;
};
ConstIterator First() const { return ConstIterator(mNodes); }
ConstIterator Last() const { return ConstIterator(mNodes + mCount); }
class Iterator : public ConstIterator {
public:
explicit Iterator(ReteNode** aNode) : ConstIterator(aNode) {}
Iterator& operator++() {
++mCurrent;
return *this; }
Iterator operator++(int) {
Iterator result(*this);
++mCurrent;
return result; }
ReteNode* operator*() const {
return *mCurrent; }
ReteNode* operator->() const {
return *mCurrent; }
bool operator==(const ConstIterator& aConstIterator) const {
return mCurrent == aConstIterator.mCurrent; }
bool operator!=(const ConstIterator& aConstIterator) const {
return mCurrent != aConstIterator.mCurrent; }
};
Iterator First() { return Iterator(mNodes); }
Iterator Last() { return Iterator(mNodes + mCount); }
int32_t Count() const { return mCount; }
protected:
ReteNode** mNodes;
int32_t mCount;
int32_t mCapacity;
};
//----------------------------------------------------------------------
/**
* A node that applies a test condition to a set of instantiations.
*
* This class provides implementations of Propagate() and Constrain()
* in terms of one simple operation, FilterInstantiations(). A node
* that is a "simple test node" in a rule network should derive from
* this class, and need only implement FilterInstantiations().
*/
class TestNode : public ReteNode
{
public:
explicit TestNode(TestNode* aParent);
/**
* Retrieve the test node's parent
* @return the test node's parent
*/
TestNode* GetParent() const { return mParent; }
/**
* Calls FilterInstantiations() on the instantiation set, and if
* the resulting set isn't empty, propagates the new set down to
* each of the test node's children.
*
* Note that the caller of Propagate is responsible for deleting
* aInstantiations if necessary as described below.
*
* Propagate may be called in update or non-update mode as indicated
* by the aIsUpdate argument. Non-update mode is used when initially
* generating results, whereas update mode is used when the datasource
* changes and new results might be available.
*
* The last node in a chain of TestNodes is always an nsInstantiationNode.
* In non-update mode, this nsInstantiationNode will cache the results
* in the query using the SetCachedResults method. The query processor
* takes these cached results and creates a nsXULTemplateResultSetRDF
* which is the enumeration returned to the template builder. This
* nsXULTemplateResultSetRDF owns the instantiations and they will be
* deleted when the nsXULTemplateResultSetRDF goes away.
*
* In update mode, the nsInstantiationNode node will iterate over the
* instantiations itself and callback to the builder to update any matches
* and generated content. If no instantiations match, then the builder
* will never be called.
*
* Thus, the difference between update and non-update modes is that in
* update mode, the results and instantiations have been already handled
* whereas in non-update mode they are expected to be returned in an
* nsXULTemplateResultSetRDF for further processing by the builder.
*
* Regardless, aTakenInstantiations will be set to true if the
* ownership over aInstantiations has been transferred to a result set.
* If set to false, the caller is still responsible for aInstantiations.
* aTakenInstantiations will be set properly even if an error occurs.
*/
virtual nsresult Propagate(InstantiationSet& aInstantiations,
bool aIsUpdate, bool& aTakenInstantiations) override;
/**
* This is called by a child node on its parent to allow the
* parent's constraints to apply to the set of instantiations.
*
* A node must iterate through the set of instantiations, and for
* each instantiation, either 1) extend the instantiation by
* adding variable-to-value assignments and memory element support
* for those assignments, or 2) remove the instantiation because
* it is inconsistent.
*
* The node must then pass the resulting set of instantiations up
* to its parent (by recursive call; we should make this iterative
* & interruptable at some point.)
*
* @param aInstantiations the set of instantiations that must
* be constrained
* @return NS_OK if no errors occurred
*/
virtual nsresult Constrain(InstantiationSet& aInstantiations);
/**
* Given a set of instantiations, filter out any that are
* inconsistent with the test node's test, and append
* variable-to-value assignments and memory element support for
* those which do pass the test node's test.
*
* @param aInstantiations the set of instantiations to be
* filtered
* @param aCantHandleYet [out] true if the instantiations do not contain
* enough information to constrain the data. May be null if this
* isn't important to the caller.
* @return NS_OK if no errors occurred.
*/
virtual nsresult FilterInstantiations(InstantiationSet& aInstantiations,
bool* aCantHandleYet) const = 0;
//XXX probably better named "ApplyConstraints" or "Discrminiate" or something
/**
* Add another node as a child of this node.
* @param aNode the node to add.
* @return NS_OK if no errors occur.
*/
nsresult AddChild(ReteNode* aNode) { return mKids.Add(aNode); }
/**
* Remove all the children of this node
* @return NS_OK if no errors occur.
*/
nsresult RemoveAllChildren() { return mKids.Clear(); }
protected:
TestNode* mParent;
ReteNodeSet mKids;
};
#endif // nsRuleNetwork_h__