Exemple #1
0
            public void Replace(Entity a, Entity b)
            {
                MemoryStore removals  = new MemoryStore();
                MemoryStore additions = new MemoryStore();

                foreach (Statement statement in statements)
                {
                    if ((statement.Subject != null && statement.Subject == a) || (statement.Predicate != null && statement.Predicate == a) || (statement.Object != null && statement.Object == a) || (statement.Meta != null && statement.Meta == a))
                    {
                        removals.Add(statement);
                        additions.Add(statement.Replace(a, b));
                    }
                }
                RemoveAll(removals.ToArray());
                Import(additions);
            }
Exemple #2
0
    public static void Main(string[] args)
    {
        if (args.Length < 2) {
            Console.WriteLine("Usage: euler.exe axioms.n3 axioms... {questions.n3 | -sparql query.sparql}");
            return;
        }

        // Load Axioms

        bool sparql = false;

        MemoryStore axioms = new MemoryStore();
        for (int i = 0; i < args.Length-1; i++) {
            if (i > 0 && i == args.Length-2 && args[i] == "-sparql") {
                sparql = true;
                break;
            }

            N3Reader axiomsreader = new N3Reader(args[i]);
            axiomsreader.BaseUri = "http://www.example.org/arbitrary/base#";
            axioms.Import(axiomsreader);
        }

        Euler engine = new Euler(axioms);

        // Load question
        if (!sparql) {
            MemoryStore question = new MemoryStore();
            question.Import(new N3Reader(args[args.Length-1]));

            Proof[] proofs = engine.Prove(null, question.ToArray());

            foreach (Proof p in proofs) {
                Console.WriteLine(p.ToString());
            }
        } else {
            using (StreamReader fs = new StreamReader(args[args.Length-1])) {
                string q = fs.ReadToEnd();

                Store store = new Store();
                store.AddReasoner(engine);

                SparqlEngine s = new SparqlEngine(q);
                s.Run(store, Console.Out);
            }
        }
    }
            public bool hasNext()
            {
                if (statements == null) {
                    System.DateTime start = System.DateTime.Now;

                    MemoryStore results = new MemoryStore();
                    StatementSink sink = results;

                    if (!source.Distinct)
                        sink = new SemWeb.Util.DistinctStatementsSink(results, !wantMetas);

                    source.Select(filter, sink);

                    wrapper.Log("SELECT: " + filter + " => " + results.StatementCount + " statements [" + (System.DateTime.Now-start) + "s]");

                    statements = results.ToArray();
                }

                return curindex + 1 < statements.Length;
            }
			private StatementIterator GetIterator(Entity[] subjects, Entity[] predicates, Resource[] objects, Entity[] metas, java.util.List litFilters, bool defaultGraph) {
				DateTime start = DateTime.Now;

				if (subjects == null && predicates == null && objects == null)
					throw new QueryExecutionException("Query would select all statements in the store.");
				
				if (subjects != null) Depersist(subjects);
				if (predicates != null) Depersist(predicates);
				if (objects != null) Depersist(objects);
				if (metas != null) Depersist(metas);
				
				if (subjects != null && subjects.Length == 0) return new StatementIterator(null);
				if (predicates != null && predicates.Length == 0) return new StatementIterator(null);
				if (objects != null && objects.Length == 0) return new StatementIterator(null);
				if (metas != null && metas.Length == 0) return new StatementIterator(null);
				
				MemoryStore results = new MemoryStore();
				StatementSink sink = results;
				
				if (!source.Distinct)
					sink = new SemWeb.Util.DistinctStatementsSink(results, defaultGraph && metas == null);

				SelectFilter filter = new SelectFilter(subjects, predicates, objects, metas);
				if (litFilters != null) {
					filter.LiteralFilters = new LiteralFilter[litFilters.size()];
					for (int i = 0; i < litFilters.size(); i++)
						filter.LiteralFilters[i] = (LiteralFilter)litFilters.get(i);
				}

				source.Select(filter, sink);
				
				Log("SELECT: " + filter + " => " + results.StatementCount + " statements [" + (DateTime.Now-start) + "s]");
				
				return new StatementIterator(results.ToArray());
			}
Exemple #5
0
		public static void MakeLean(Store store, SelectableSource relativeTo, StatementSink removed) {
			// Break the data source into MSGs.  Make each MSG
			// lean first (in isolation).  Then check each lean MSG
			// to see if it's already entailed by the whole store,
			// or by relativeTo if it's provided (not null).
		
			MSG.Graph[] msgs = MSG.FindMSGs(store, true);
			
			foreach (MSG.Graph msgg in msgs) {
				// Load the MSG into memory.
				MemoryStore msg = new MemoryStore(msgg); // unnecessary duplication...

				// Make this MSG lean.  The "right" thing to do is
				// to consider all of the 'connected' subgraphs of MSG
				// against the whole store, rather than the MSG in
				// isolation.  But that gets much too expensive.
				MemoryStore msgremoved = new MemoryStore();
				MakeLeanMSG(new Store(msg), msgg.GetBNodes(), msgremoved);
				
				// Whatever was removed from msg, remove it from the main graph.
				store.RemoveAll(msgremoved.ToArray());
				
				// And track what was removed.
				if (removed != null) msgremoved.Select(removed);
				
				// If this MSG is now (somehow) empty (shouldn't happen,
				// but one never knows), don't test for entailment.
				if (msg.StatementCount == 0) continue;

				// Remove this MSG if it is already entailed.
				
				// The GraphMatch will treat all blank nodes in
				// msg as variables.
				GraphMatch match = new GraphMatch(msg);
				QueryResultBuffer sink = new QueryResultBuffer();
				match.Run(new SubtractionSource(store, msg), sink);
				if (sink.Bindings.Count > 0) {
					// This MSG can be removed.
					store.RemoveAll(msg.ToArray());
					if (removed != null) msg.Select(removed);
				} else if (relativeTo != null) {
					match.Run(relativeTo, sink);
					if (sink.Bindings.Count > 0) {
						// This MSG can be removed.
						store.RemoveAll(msg.ToArray());
						if (removed != null) msg.Select(removed);
					}
				}
			}
		}
Exemple #6
0
        // The next few routines convert a set of axioms from a StatementSource
        // into a data structure of use for the algorithm, with Sequents and things.
        private static Hashtable RulesToCases(StatementSource rules)
        {
            Hashtable cases = new Hashtable();
            MemoryStore rules_store = new MemoryStore(rules);
            foreach (Statement p in rules_store) {
                if (p.Meta == Statement.DefaultMeta) {
                    if (p.Predicate == entLOGIMPLIES && p.Object is Entity) {
                        MemoryStore body = new MemoryStore();
                        MemoryStore head = new MemoryStore();

                        rules_store.Select(new Statement(null, null, null,  (Entity)p.Subject), new RemoveMeta(body));
                        rules_store.Select(new Statement(null, null, null,  (Entity)p.Object), new RemoveMeta(head));

                        // Any variables in the head not bound in the body represent existentially closed bnodes.
                        // (Euler's OWL test case does this. Wish they had used bnodes instead of vars...)
                        ResSet bodyvars = new ResSet();
                        foreach (Statement b in body) {
                            if (b.Subject is Variable) bodyvars.Add(b.Subject);
                            if (b.Predicate is Variable) bodyvars.Add(b.Predicate);
                            if (b.Object is Variable) bodyvars.Add(b.Object);
                        }
                        foreach (Entity v in head.GetEntities()) {
                            if (v is Variable && !bodyvars.Contains(v))
                                head.Replace(v, new BNode(((Variable)v).LocalName));
                        }

                        // Replace (...) lists in the body that are tied to the subjects
                        // of user predicates with callArgs objects.
                        Hashtable callArgs = new Hashtable();
                        CollectCallArgs(body, callArgs);

                        // Rules can't have more than one statement in their
                        // consequent.  The best we can do is break up
                        // the consequent into multiple rules.  (Since all head
                        // variables are bound in body, it's equivalent...?)
                        foreach (Statement h in head)
                            AddSequent(cases, new Sequent(h, body.ToArray(), callArgs));
                    } else {
                        AddSequent(cases, new Sequent(p, new Statement[0], null));
                    }
                }
            }

            return cases;
        }
		public override void Replace(Entity a, Entity b) {
			MemoryStore removals = new MemoryStore();
			MemoryStore additions = new MemoryStore();
			foreach (Statement statement in statements) {
				if ((statement.Subject != null && statement.Subject == a) || (statement.Predicate != null && statement.Predicate == a) || (statement.Object != null && statement.Object == a) || (statement.Meta != null && statement.Meta == a)) {
					removals.Add(statement);
					additions.Add(statement.Replace(a, b));
				}
			}
			RemoveAll(removals.ToArray());
			Import(additions);
		}