Over the years, I've had an on-again, off-again interest in Rules Engines. However, as Martin Fowler points out, it is often more pragmatic to build a custom engine. A custom engine can be as simple as a properties file modelled after an awk script (ie, {pattern => action} pairs). More complex rules, ie multiple pattern matches in a certain sequence leading to a single complex action, can also be modeled by doing a Java variant of the awk strategy, ie {Predicate => Closure}. Where Rules Engines shine, however, is when you need to do rule chaining or when the structure of the rules themselves (rather than their values) change very rapidly.
Motivation
I actually set out to learn Jena Rules using the Semantic Web Programming book as a guide. Midway through that exercise, it occurred to me that Prolog would be a cleaner and almost drop-in replacement to the rather verbose Turtle syntax. Apparently the Semantic Web community thinks otherwise, since Turtle stands for Terse RDF Triple language. I haven't actually used Prolog before this, although I've read code snippets in articles once or twice (but not recently), so the realization was almost like an epiphany.
Which Prolog?
I initially download GNU-Prolog because it was available from the yum repository, but then I decided to go with SWI-Prolog, because there is a Netbeans plugin available for it, and because it offers a Java-Prolog Interface (JPL) (haven't tried this yet). Because SWI-Prolog did not have an RPM for my AMD-64 laptop, I had to build it from source, but I did not have any problems doing that.
Learning Prolog
There are quite a few Prolog tutorials available on the Web, but most focus on trying to use it as a general-purpose programming language. Since I intended to use Prolog only for its logic programming facilities, I found the Learn Prolog Now! and Adventure in Prolog online books more suitable. The first one is based on SWI-Prolog and the second on Amzi! Prolog, but examples from both worked fine for me.
The Fact Base
A Prolog program consists of facts, rules and queries. In order to keep my fact base similar to the ontology model, I decided to model my facts as triples (isTriple/3 in Prolog, since it takes three arguments), as shown below. Each of the subject, predicate and object can either be an Atom or a Compound Term (you have to make this decision at modeling time). I've just used Atoms in my example.
1 2 3 4 | isTriple(subject, predicate, object).
% if we want predicates to have a property such as weight, we
% can model it as a compound term as shown below:
isTriple(subject, predicate(name, weight), object).
|
I used a simple Java program to generate my initial fact base of about 500+ triples from the sample wine.rdf file. It uses Jena to parse the file and write out the facts into a flat file. Unlike my previous usage, where I tried to map inverse relationships using an Enum, this time I only consider the relationships that exist in the wine.rdf file itself, and use rules to build the inverse relations. Since my subject and object names start with upper-case, I prepended an 'a' to make it conform to Prolog's syntax rules. You can run this with a main() class or write a unit test. I used a unit test, but I am not showing this since its so trivial.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 | // Source: src/main/java/net/sf/jtmt/inferencing/prolog/Owl2PrologFactGenerator.java
package net.sf.jtmt.inferencing.prolog;
import java.io.FileWriter;
import java.io.PrintWriter;
import org.apache.commons.lang.StringUtils;
import com.hp.hpl.jena.graph.Node;
import com.hp.hpl.jena.graph.Node_URI;
import com.hp.hpl.jena.graph.Triple;
import com.hp.hpl.jena.rdf.model.Model;
import com.hp.hpl.jena.rdf.model.ModelFactory;
import com.hp.hpl.jena.rdf.model.Statement;
import com.hp.hpl.jena.rdf.model.StmtIterator;
/**
* Reads an OWL file representing an ontology, and outputs a Prolog
* fact base.
*/
public class Owl2PrologFactGenerator {
private String inputOwlFilename;
private String outputPrologFilename;
public void setInputOwlFilename(String inputOwlFilename) {
this.inputOwlFilename = inputOwlFilename;
}
public void setOutputPrologFilename(String outputPrologFilename) {
this.outputPrologFilename = outputPrologFilename;
}
public void generate() throws Exception {
PrintWriter prologWriter =
new PrintWriter(new FileWriter(outputPrologFilename), true);
Model model = ModelFactory.createDefaultModel();
model.read(inputOwlFilename);
StmtIterator sit = model.listStatements();
while (sit.hasNext()) {
Statement st = sit.next();
Triple triple = st.asTriple();
String prologFact = getPrologFact(triple);
if (StringUtils.isNotEmpty(prologFact)) {
prologWriter.println(getPrologFact(triple));
}
}
model.close();
prologWriter.flush();
prologWriter.close();
}
private String getPrologFact(Triple triple) {
StringBuilder buf = new StringBuilder();
Node subject = triple.getSubject();
Node object = triple.getObject();
if ((subject instanceof Node_URI) &&
(object instanceof Node_URI)) {
buf.append("isTriple(a").
append(triple.getSubject().getLocalName()).
append(",").
append(triple.getPredicate().getLocalName()).
append(",a").
append(triple.getObject().getLocalName()).
append(").");
}
return buf.toString();
}
}
|
My output file contains the fact base in Prolog syntax. Here is a partial listing, to show you how it looks. The full source file (including the rules and the testing function, described below) is available here if you want it.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 | % Source: src/main/prolog/net/sf/jtmt/inferencing/prolog/wine_facts.pro
% ...
isTriple(aCorbansPrivateBinSauvignonBlanc,hasBody,aFull).
isTriple(aCorbansPrivateBinSauvignonBlanc,hasFlavor,aStrong).
isTriple(aCorbansPrivateBinSauvignonBlanc,hasSugar,aDry).
isTriple(aCorbansPrivateBinSauvignonBlanc,hasMaker,aCorbans).
isTriple(aCorbansPrivateBinSauvignonBlanc,locatedIn,aNewZealandRegion).
isTriple(aCorbansPrivateBinSauvignonBlanc,type,aSauvignonBlanc).
isTriple(aSevreEtMaineMuscadet,hasMaker,aSevreEtMaine).
isTriple(aSevreEtMaineMuscadet,type,aMuscadet).
isTriple(aWineFlavor,subClassOf,aWineTaste).
isTriple(aWineFlavor,type,aClass).
isTriple(aEdnaValleyRegion,locatedIn,aCaliforniaRegion).
isTriple(aEdnaValleyRegion,type,aRegion).
...
|
Adding Rules
The first step is adding the inverse relationships using Prolog rules. This is quite simple, as shown below:
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 | % Source: src/main/prolog/net/sf/jtmt/inferencing/prolog/wine_facts.pro
% ...
% --------------------------------------------------------------
% rules to augment the generated facts.
% --------------------------------------------------------------
% rules to generate inverse relationships where applicable
isTriple(Subject, isVintageYearOf, Object) :-
isTriple(Object, hasVintageYear, Subject).
isTriple(Subject, regionContains, Object) :-
isTriple(Object, locatedIn, Subject).
isTriple(Subject, mainIngredient, Object) :-
isTriple(Object, mainIngredient, Subject).
isTriple(Subject, isFlavorOf, Object) :-
isTriple(Object, hasFlavor, Subject).
isTriple(Subject, isColorOf, Object) :-
isTriple(Object, hasColor, Subject).
isTriple(Subject, isSugarContentOf, Object) :-
isTriple(Object, hasSugar, Subject).
isTriple(Subject, isBodyOf, Object) :-
isTriple(Object, hasBody, Subject).
isTriple(Subject, madeBy, Object) :-
isTriple(Object, hasMaker, Subject).
isTriple(Subject, hasInstance, Object) :-
isTriple(Object, type, Subject).
isTriple(Subject, superClassOf, Object) :-
isTriple(Object, subClassOf, Subject).
|
Nothing fancy here, as you can see - we just create new isTriple rules by switching the subject and object around, and replacing the predicate with its inverse. These are simple examples of generating relationships algebrically from existing ones, we have slightly more complex examples later. Trying out some of these rules in the SWI-Prolog listener (AKA interactive shell in Python, or REPL in Lisp) shows that they work. Note that the last false indicates that there are no more matches for this rule.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 | sujit@sirocco:~$ pl
Welcome to SWI-Prolog (Multi-threaded, 64 bits, Version 5.6.64)
Copyright (c) 1990-2008 University of Amsterdam.
SWI-Prolog comes with ABSOLUTELY NO WARRANTY. This is free software,
and you are welcome to redistribute it under certain conditions.
Please visit http://www.swi-prolog.org for details.
?- consult('wine_facts.pro').
% wine_facts.pro compiled 0.02 sec, 109,832 bytes
true.
?- isTriple(aCongressSpringsSemillon, hasSugar, aDry).
true ;
false.
?- isTriple(aDry, isSugarContentOf, aCongressSpringsSemillon).
true ;
false.
|
I then decided to add relations which don't already exist, using slightly more complex rules (involving recursion) to generate relationships from existing ones. Here is the snippet for these rules from my wine_facts.pro file.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 | % Source: src/main/prolog/net/sf/jtmt/inferencing/prolog/wine_facts.pro
% ...
% rule to find all wines produced by a given region (region can be at any
% level, ie. country (USRegion), state (CaliforniaRegion), or location within
% state (SantaCruzMountainsRegion). Only wines should be listed. We do this
% by ensuring that a Wine has a valid maker.
isTriple(Region, produces, Wine) :- isTriple(Region, regionContains, Wine),
isTriple(Wine, hasMaker, _).
isTriple(Region, produces, Wine) :- isTriple(Region, regionContains, X),
isTriple(X, produces, Wine),
isTriple(Wine, hasMaker, _).
% rule to find out the region for which the wine is produced. Only the
% regions should be listed. We do this by ensuring that a Region has type
% aRegion.
isTriple(Wine, producedBy, Region) :- isTriple(Region, regionContains, Wine),
isTriple(Region, type, aRegion).
isTriple(Wine, producedBy, Region) :- isTriple(Region, regionContains, X),
isTriple(X, produces, Wine),
isTriple(X, type, aRegion).
|
As before we can test these rules from the SWI-Prolog shell. However, I also built a little Prolog function that allows you to do Query-By-Example.
1 2 3 4 5 6 7 8 9 | % Source: src/main/prolog/net/sf/jtmt/inferencing/prolog/wine_facts.pro
% --------------------------------------------------------------
% simple query-by-example testing tool
% --------------------------------------------------------------
test(Subject,Predicate,Object) :- isTriple(Subject, Predicate, Object),
tab(2), write('('), write(Subject),
write(','), write(Predicate),
write(','), write(Object),
write(')'), nl, fail.
|
Running my test cases (commented out in the source file, since I could not get them to work in batch mode) in the SWI-Prolog listener returns the following (expected) results.
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 | ?- consult('wine_facts.pro').
% wine_facts.pro compiled 0.02 sec, 109,832 bytes
true.
?- test(aUSRegion, produces, X).
(aUSRegion,produces,aMountEdenVineyardEstatePinotNoir)
(aUSRegion,produces,aMountEdenVineyardEdnaValleyChardonnay)
(aUSRegion,produces,aFormanChardonnay)
(aUSRegion,produces,aWhitehallLaneCabernetFranc)
(aUSRegion,produces,aFormanCabernetSauvignon)
(aUSRegion,produces,aElyseZinfandel)
(aUSRegion,produces,aSeanThackreySiriusPetiteSyrah)
(aUSRegion,produces,aPageMillWineryCabernetSauvignon)
(aUSRegion,produces,aBancroftChardonnay)
(aUSRegion,produces,aSaucelitoCanyonZinfandel)
(aUSRegion,produces,aSaucelitoCanyonZinfandel1998)
(aUSRegion,produces,aMariettaPetiteSyrah)
(aUSRegion,produces,aMariettaZinfandel)
(aUSRegion,produces,aGaryFarrellMerlot)
(aUSRegion,produces,aPeterMccoyChardonnay)
(aUSRegion,produces,aMariettaOldVinesRed)
(aUSRegion,produces,aCotturiZinfandel)
(aUSRegion,produces,aMariettaCabernetSauvignon)
(aUSRegion,produces,aVentanaCheninBlanc)
(aUSRegion,produces,aLaneTannerPinotNoir)
(aUSRegion,produces,aFoxenCheninBlanc)
(aUSRegion,produces,aSantaCruzMountainVineyardCabernetSauvignon)
(aUSRegion,produces,aStGenevieveTexasWhite)
false.
?- test(X, produces, aLaneTannerPinotNoir).
(aSantaBarbaraRegion,produces,aLaneTannerPinotNoir)
(aCaliforniaRegion,produces,aLaneTannerPinotNoir)
(aUSRegion,produces,aLaneTannerPinotNoir)
false.
?- test(aTexasRegion, produces, X).
(aTexasRegion,produces,aStGenevieveTexasWhite)
false.
?- test(X, produces, aStGenevieveTexasWhite).
(aCentralTexasRegion,produces,aStGenevieveTexasWhite)
(aTexasRegion,produces,aStGenevieveTexasWhite)
(aUSRegion,produces,aStGenevieveTexasWhite)
false.
?- test(X, producedBy, aUSRegion).
(aCaliforniaRegion,producedBy,aUSRegion)
(aTexasRegion,producedBy,aUSRegion)
(aMountEdenVineyardEstatePinotNoir,producedBy,aUSRegion)
(aMountEdenVineyardEdnaValleyChardonnay,producedBy,aUSRegion)
(aFormanChardonnay,producedBy,aUSRegion)
(aWhitehallLaneCabernetFranc,producedBy,aUSRegion)
(aFormanCabernetSauvignon,producedBy,aUSRegion)
(aElyseZinfandel,producedBy,aUSRegion)
(aSeanThackreySiriusPetiteSyrah,producedBy,aUSRegion)
(aPageMillWineryCabernetSauvignon,producedBy,aUSRegion)
(aBancroftChardonnay,producedBy,aUSRegion)
(aSaucelitoCanyonZinfandel,producedBy,aUSRegion)
(aSaucelitoCanyonZinfandel1998,producedBy,aUSRegion)
(aMariettaPetiteSyrah,producedBy,aUSRegion)
(aMariettaZinfandel,producedBy,aUSRegion)
(aGaryFarrellMerlot,producedBy,aUSRegion)
(aPeterMccoyChardonnay,producedBy,aUSRegion)
(aMariettaOldVinesRed,producedBy,aUSRegion)
(aCotturiZinfandel,producedBy,aUSRegion)
(aMariettaCabernetSauvignon,producedBy,aUSRegion)
(aVentanaCheninBlanc,producedBy,aUSRegion)
(aLaneTannerPinotNoir,producedBy,aUSRegion)
(aFoxenCheninBlanc,producedBy,aUSRegion)
(aSantaCruzMountainVineyardCabernetSauvignon,producedBy,aUSRegion)
(aStGenevieveTexasWhite,producedBy,aUSRegion)
false.
?- test(X, producedBy, aTexasRegion).
(aCentralTexasRegion,producedBy,aTexasRegion)
(aStGenevieveTexasWhite,producedBy,aTexasRegion)
false.
?- test(aLaneTannerPinotNoir, producedBy, X).
(aLaneTannerPinotNoir,producedBy,aSantaBarbaraRegion)
(aLaneTannerPinotNoir,producedBy,aCaliforniaRegion)
(aLaneTannerPinotNoir,producedBy,aUSRegion)
false.
?- test(aStGenevieveTexasWhite, producedBy, X).
(aStGenevieveTexasWhite,producedBy,aCentralTexasRegion)
(aStGenevieveTexasWhite,producedBy,aTexasRegion)
(aStGenevieveTexasWhite,producedBy,aUSRegion)
false.
|
Conclusion
I found this article (PDF) describing an attempt to model OWL rules using Prolog, so perhaps this idea is not as novel as it seemed to me at first. Prolog uses backward inferencing, which means that the rule based facts are recomputed on demand, rather than at the point of being asserted into the factbase. For a query-heavy system, which most rule based systems tend to be, this can have an impact on performance. But I think an application built around Prolog's rule engine can get around this by identifying a fact based on its origin, and generating and caching rule based facts at the point of assertion. If a rule is dropped or modified, the facts based on that rule could be recomputed and cached automatically.
In terms of simplicity of syntax alone, I think a Prolog based rule definition system would be a welcome addition to the Semantic Web Programmer's toolkit. The pattern-based query by example I have described is also likely to be much simpler and easier to use than the more imperative SPARQL query language used to query OWL ontologies.
However, I do plan to learn how to build rules using the tools and languages in the Jena framework, just because it is what I am more likely to use in a typical Semantic Web development environment.
There is a package for SWI-Prolog called Thea that allows for translation of OWL2 ontologies to rules, as well as limited backward chaining strategies. See:
ReplyDeletehttp://github.com/vangelisv/thea
You can also do reverse translations for a limited subset of prolog. See:
http://blipkit.wordpress.com/2009/06/19/translating-between-logic-programs-and-owlswrl/
Thank you Chris, I took a quick look at Thea, will take a more detailed look later.
ReplyDeleteBut Mr Cris How to use THEA. I am not getting anything. I am a biginner
ReplyDeleteHi, you may want to post this query on Chris's blog.
ReplyDeleteHi, is the source code still available for this example? If not how did you create the inverse rules in prolog?
ReplyDeleteHi Chathumina, sorry for the delay in response, and no, unfortunately I am almost certain I don't have the source code for this anymore. That said, I believe all the code is in the article itself. Its been a while, but I think the inverse rules are also in the article. Looking at the rules themselves, I just did two inversions. First is to invert is_property_of(A, B) to has_property(B, A) and the second is is_subclass_of(A, B) to is_superclass_of(B, A). Both are common-sense driven, no specialized process behind it.
ReplyDelete