Java Code Examples for com.bigdata.rdf.store.AbstractTripleStore#isQuads()
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com.bigdata.rdf.store.AbstractTripleStore#isQuads() .
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Example 1
Source File: BigdataGASEngine.java From database with GNU General Public License v2.0 | 5 votes |
private final SPOKeyOrder getKeyOrder(final AbstractTripleStore kb, final boolean inEdges) { final SPOKeyOrder keyOrder; if (inEdges) { // in-edges: OSP / OCSP : [u] is the Object. keyOrder = kb.isQuads() ? SPOKeyOrder.OCSP : SPOKeyOrder.OSP; } else { // out-edges: SPO / (SPOC|SOPC) : [u] is the Subject. keyOrder = kb.isQuads() ? SPOKeyOrder.SPOC : SPOKeyOrder.SPO; } return keyOrder; }
Example 2
Source File: TestSPOAccessPath.java From database with GNU General Public License v2.0 | 4 votes |
/** * There are 8 distinct triple pattern bindings for a triple store that * select among 3 distinct access paths. */ public void test_getAccessPath() { final AbstractTripleStore store = getStore(); // constants used for s,p,o,c when bound. 0L used when unbound. final IV<?,?> S = factory.newTermId(VTE.URI, 1); final IV<?,?> P = factory.newTermId(VTE.URI, 2); final IV<?,?> O = factory.newTermId(VTE.URI, 3); final IV<?,?> C = factory.newTermId(VTE.URI, 4); final IV<?,?> _ = factory.newTermId(VTE.URI, 0); try { final SPORelation r = store.getSPORelation(); if (store.isQuads()) { /* * For a quad store there are 16 distinct binding patterns that * select among 6 distinct access paths. there are some quad * patterns which could be mapped onto more than one access * path, but the code here checks the expected mapping. These * mappings are similar to those in YARS2, but are the mappings * generated by the "Magic" tuple logic. */ // SPOC assertEquals(SPOKeyOrder.SPOC, r.getAccessPath(_, _, _, _).getKeyOrder()); assertEquals(SPOKeyOrder.SPOC, r.getAccessPath(S, _, _, _).getKeyOrder()); assertEquals(SPOKeyOrder.SPOC, r.getAccessPath(S, P, _, _).getKeyOrder()); assertEquals(SPOKeyOrder.SPOC, r.getAccessPath(S, P, O, _).getKeyOrder()); assertEquals(SPOKeyOrder.SPOC, r.getAccessPath(S, P, O, C).getKeyOrder()); // POCS assertEquals(SPOKeyOrder.POCS, r.getAccessPath(_, P, _, _).getKeyOrder()); assertEquals(SPOKeyOrder.POCS, r.getAccessPath(_, P, O, _).getKeyOrder()); assertEquals(SPOKeyOrder.POCS, r.getAccessPath(_, P, O, C).getKeyOrder()); // OCSP assertEquals(SPOKeyOrder.OCSP, r.getAccessPath(_, _, O, _).getKeyOrder()); assertEquals(SPOKeyOrder.OCSP, r.getAccessPath(_, _, O, C).getKeyOrder()); assertEquals(SPOKeyOrder.OCSP, r.getAccessPath(S, _, O, C).getKeyOrder()); // CSPO assertEquals(SPOKeyOrder.CSPO, r.getAccessPath(_, _, _, C).getKeyOrder()); assertEquals(SPOKeyOrder.CSPO, r.getAccessPath(S, _, _, C).getKeyOrder()); assertEquals(SPOKeyOrder.CSPO, r.getAccessPath(S, P, _, C).getKeyOrder()); // PCSO assertEquals(SPOKeyOrder.PCSO, r.getAccessPath(_, P, _, C).getKeyOrder()); // SOPC assertEquals(SPOKeyOrder.SOPC, r.getAccessPath(S, _, O, _).getKeyOrder()); } else { assertEquals(SPOKeyOrder.SPO, r.getAccessPath(NULL, NULL, NULL, NULL).getKeyOrder()); assertEquals(SPOKeyOrder.SPO, r.getAccessPath(S, NULL, NULL, NULL).getKeyOrder()); assertEquals(SPOKeyOrder.SPO, r.getAccessPath(S, S, NULL, NULL) .getKeyOrder()); assertEquals(SPOKeyOrder.SPO, r.getAccessPath(S, S, S, NULL) .getKeyOrder()); assertEquals(SPOKeyOrder.POS, r.getAccessPath(NULL, S, NULL, NULL).getKeyOrder()); assertEquals(SPOKeyOrder.POS, r.getAccessPath(NULL, S, S, NULL) .getKeyOrder()); assertEquals(SPOKeyOrder.OSP, r.getAccessPath(NULL, NULL, S, NULL).getKeyOrder()); assertEquals(SPOKeyOrder.OSP, r.getAccessPath(S, NULL, S, NULL) .getKeyOrder()); } } finally { store.__tearDownUnitTest(); } }
Example 3
Source File: AbstractTestNanoSparqlClient.java From database with GNU General Public License v2.0 | 4 votes |
protected Server newFixture(final String lnamespace) throws Exception { final IIndexManager indexManager = getIndexManager(); final Properties properties = getProperties(); // Create the triple store instance. createTripleStore(indexManager, lnamespace, properties); // Open an unisolated connection on that namespace and figure out what // mode the namespace is using. { final BigdataSail sail = new BigdataSail(lnamespace, indexManager); try { sail.initialize(); final BigdataSailConnection con = sail.getUnisolatedConnection(); try { final AbstractTripleStore tripleStore = con.getTripleStore(); if (tripleStore.isStatementIdentifiers()) { testMode = TestMode.sids; } else if (tripleStore.isQuads()) { testMode = TestMode.quads; } else { testMode = TestMode.triples; } } finally { con.close(); } } finally { sail.shutDown(); } } final Map<String, String> initParams = new LinkedHashMap<String, String>(); { initParams.put(ConfigParams.NAMESPACE, lnamespace); initParams.put(ConfigParams.CREATE, "false"); } // Start server for that kb instance. final Server fixture = NanoSparqlServer.newInstance(0/* port */, indexManager, initParams); fixture.start(); return fixture; }
Example 4
Source File: ASTConstructIterator.java From database with GNU General Public License v2.0 | 4 votes |
private IFilterTest createDistinctFilter(final AbstractTripleStore tripleStore, final ConstructNode construct, final GraphPatternGroup<?> whereClause) { /* * Setup the DISTINCT SPO filter. * * Note: CONSTRUCT is sometimes used to materialize all triples for some * triple pattern. For that use case, the triples are (of necessity) * already DISTINCT. Therefore, when there is a single triple pattern in * the WHERE clause and a single template in the CONSTRUCT, we DO NOT * impose a DISTINCT filter. This saves resources when the CONSTRUCTed * graph is large. */ final boolean distinctQuads = construct.isDistinctQuads() && tripleStore.isQuads() && hasMixedQuadData(templates); final boolean nativeDistinct = construct.isNativeDistinct(); if (!constructDistinctSPO) { /** * DISTINCT SPO filter was disabled by a query hint. The output is * NOT guaranteed to be distinct. * * @see BLZG-1341. */ // No filter will be imposed. return null; } if (nativeDistinct && construct.isDistinctQuads()) { flagToCheckNativeDistinctQuadsInvocationForJUnitTesting = true; } /* * Test the CONSTRUCT clause and WHERE clause to see if we need to * impose a DISTINCT SPO filter. */ final boolean isObviouslyDistinct = isObviouslyDistinct(tripleStore.isQuads(), templates, whereClause); if (isObviouslyDistinct) { // Do not impose a DISTINCT filter. return null; } if (distinctQuads) { if (nativeDistinct) { return createNativeDistinctQuadsFilter(construct); } else { return createHashDistinctQuadsFilter(construct); } } else { if (nativeDistinct) { return createNativeDistinctTripleFilter(construct); } else { // JVM Based DISTINCT filter. return new DistinctFilter.DistinctFilterImpl(construct); } } }
Example 5
Source File: TestAsynchronousStatementBufferFactory.java From database with GNU General Public License v2.0 | 3 votes |
/** * Test with the "broken.rdf" data set (does not contain valid RDF). This * tests that the factory will shutdown correctly if there are processing * errors. * * @throws Exception */ public void test_loadFails() throws Exception { final String resource = "/com/bigdata/rdf/rio/broken.rdf"; final AbstractTripleStore store = getStore(); try { if(!(store.getIndexManager() instanceof AbstractScaleOutFederation)) { log.warn("Test requires scale-out index views."); return; } if (store.isQuads()) { log.warn("Quads not supported yet."); return; } // only do load since we expect an error to be reported. final AsynchronousStatementBufferFactory<BigdataStatement, File> factory = doLoad2( store, new File(resource), parallel); assertEquals("errorCount", 1, factory.getDocumentErrorCount()); } finally { store.__tearDownUnitTest(); } }
Example 6
Source File: ExportKB.java From database with GNU General Public License v2.0 | 3 votes |
/** * * @param conn * The connection. * @param kbdir * The directory into which the exported properties and RDF data * will be written. * @param format * The {@link RDFFormat} to use when exporting the data. * @param includeInferred * When <code>true</code> inferences and axioms will also be * exported. Otherwise just the explicitly given (aka told) * triples/quads will be exported. */ public ExportKB(final BigdataSailConnection conn, final File kbdir, final RDFFormat format, final boolean includeInferred) { if (conn == null) throw new IllegalArgumentException("KB not specified."); if (kbdir == null) throw new IllegalArgumentException( "Output directory not specified."); if (format == null) throw new IllegalArgumentException("RDFFormat not specified."); final AbstractTripleStore kb = conn.getTripleStore(); if (kb.isStatementIdentifiers() && !RDFFormat.RDFXML.equals(format)) throw new IllegalArgumentException( "SIDs mode requires RDF/XML interchange."); if (kb.isQuads() && !format.supportsContexts()) throw new IllegalArgumentException( "RDFFormat does not support quads: " + format); this.conn = conn; // this.kb = kb; this.namespace = kb.getNamespace(); this.kbdir = kbdir; this.format = format; this.includeInferred = includeInferred; }
Example 7
Source File: VoID.java From database with GNU General Public License v2.0 | 2 votes |
/** * Return an array of the distinct predicates in the KB ordered by their * descending frequency of use. The {@link IV}s in the returned array will * have been resolved to the corresponding {@link BigdataURI}s which can be * accessed using {@link IV#getValue()}. * * @param kb * The KB instance. */ protected static IVCount[] predicateUsage(final AbstractTripleStore kb) { final SPORelation r = kb.getSPORelation(); if (r.oneAccessPath) { // The necessary index (POS or POCS) does not exist. throw new UnsupportedOperationException(); } final boolean quads = kb.isQuads(); // the index to use for distinct predicate scan. final SPOKeyOrder keyOrder = quads ? SPOKeyOrder.POCS : SPOKeyOrder.POS; // visit distinct term identifiers for predicate position on that index. @SuppressWarnings("rawtypes") final IChunkedIterator<IV> itr = r.distinctTermScan(keyOrder); // resolve term identifiers to terms efficiently during iteration. final BigdataValueIterator itr2 = new BigdataValueIteratorImpl( kb/* resolveTerms */, itr); try { final Set<IV<?,?>> ivs = new LinkedHashSet<IV<?,?>>(); final Map<IV<?, ?>, IVCount> counts = new LinkedHashMap<IV<?, ?>, IVCount>(); while (itr2.hasNext()) { final BigdataValue term = itr2.next(); final IV<?,?> iv = term.getIV(); final long n = r.getAccessPath(null, iv, null, null) .rangeCount(false/* exact */); ivs.add(iv); counts.put(iv, new IVCount(iv, n)); } // Batch resolve IVs to Values final Map<IV<?, ?>, BigdataValue> x = kb.getLexiconRelation() .getTerms(ivs); for (Map.Entry<IV<?, ?>, BigdataValue> e : x.entrySet()) { final IVCount count = counts.get(e.getKey()); count.setValue(e.getValue()); } final IVCount[] a = counts.values().toArray( new IVCount[counts.size()]); // Order by descending count. Arrays.sort(a); return a; } finally { itr2.close(); } }
Example 8
Source File: VoID.java From database with GNU General Public License v2.0 | 2 votes |
/** * Return the predicate partition statistics for the named graph. * * @param kb * The KB instance. * @param civ * The {@link IV} of a named graph (required). * * @return The predicate partition statistics for that named graph. Only * predicate partitions which are non-empty are returned. */ protected static IVCount[] predicateUsage(final AbstractTripleStore kb, final IV<?, ?> civ, final IVCount[] predicatePartitionCounts) { final SPORelation r = kb.getSPORelation(); final boolean quads = kb.isQuads(); if (!quads) { // Named graph only valid in quads mode. throw new IllegalArgumentException(); } // The non-zero counts. final List<IVCount> counts = new LinkedList<IVCount>(); // Check the known non-empty predicate partitions. for(IVCount in : predicatePartitionCounts){ final long n = r.getAccessPath(null, in.iv, null, civ).rangeCount( false/* exact */); if (n == 0) continue; final IVCount out = new IVCount(in.iv, n); out.setValue(in.getValue()); counts.add(out); } final IVCount[] a = counts.toArray(new IVCount[counts.size()]); // Order by descending count. Arrays.sort(a); return a; }
Example 9
Source File: VoID.java From database with GNU General Public License v2.0 | 2 votes |
/** * Return the class partition statistics for the named graph. * * @param kb * The KB instance. * @param civ * The {@link IV} of a named graph (required). * * @return The class partition statistics for that named graph. Only class * partitions which are non-empty are returned. */ protected static IVCount[] classUsage(final AbstractTripleStore kb, final IV<?, ?> civ, final IVCount[] classPartitionCounts) { final SPORelation r = kb.getSPORelation(); final boolean quads = kb.isQuads(); if (!quads) { // Named graph only valid in quads mode. throw new IllegalArgumentException(); } // Resolve IV for rdf:type final BigdataURI rdfType = kb.getValueFactory().asValue(RDF.TYPE); kb.getLexiconRelation().addTerms(new BigdataValue[] { rdfType }, 1/* numTerms */, true/* readOnly */); if (rdfType.getIV() == null) { // No rdf:type assertions since rdf:type is unknown term. return new IVCount[0]; } // The non-zero counts. final List<IVCount> counts = new LinkedList<IVCount>(); // Check the known non-empty predicate partitions. for (IVCount in : classPartitionCounts) { final long n = r.getAccessPath(null, rdfType.getIV()/* p */, in.iv/* o */, civ).rangeCount(false/* exact */); if (n == 0) continue; final IVCount out = new IVCount(in.iv, n); out.setValue(in.getValue()); counts.add(out); } final IVCount[] a = counts.toArray(new IVCount[counts.size()]); // Order by descending count. Arrays.sort(a); return a; }