public boolean isInputParameterSet(boolean left) { Rule r = this.kernelRule; this.addToAttrContext((VarTuple) r.getAttrContext().getVariables()); if (r.getMatch() != null) { this.adaptAttrContextValues(r.getMatch().getAttrContext()); } else { this.adaptAttrContextValues(r.getAttrContext()); } // ((VarTuple) this.getAttrContext().getVariables()).showVariables(); for (int i = 0; i < this.multiRules.size(); i++) { r = this.multiRules.get(i); if (r.isEnabled()) { this.addToAttrContext((VarTuple) r.getAttrContext().getVariables()); if (r.getMatch() != null) { this.adaptAttrContextValues(r.getMatch().getAttrContext()); } } } // ((VarTuple) this.getAttrContext().getVariables()).showVariables(); return isInputParameterSet(this.getAttrContext(), left); }
/** * Propagate application conditions (NAC / PAC) of the kernel rule along embedding morphism of * each multi rule (left embedding: kernel.LHS -> multi.LHS, right embedding: kernel.RHS -> * multi.RHS). Propagated application conditions are added to the list of the own application * conditions of each multi rule. */ public void propagateApplCondsOfKernelToMultiRules() { if (!this.shiftDone) { for (int j = 0; j < this.multiRules.size(); j++) { Rule mRule = this.multiRules.get(j); if (mRule.isEnabled()) { shiftApplCondsOfKernelToMultiRule((MultiRule) mRule); } } this.shiftDone = true; } }
/** * Computes if the first rule exclude the second rule. The result is added to the container. * * @param r1 The first rule. * @param r2 The second rule. */ protected synchronized void computeCritical(Rule r1, Rule r2) { Report.trace("LayeredDependencyPairContainer: starte computeCritical", 2); // System.out.println("LayeredDependencyPairContainer.computeCritical(r1, // r2): "+r1.getName()+" "+r2.getName()+" "+this.getEntry(r1, // r2).state); // mark Entry if (!r1.isEnabled() || !r2.isEnabled()) { // test disabled rule this.getEntry(r1, r2).state = Entry.DISABLED; addEntry(r1, r2, false, null); addQuadruple(this.excludeContainer, r1, r2, false, null); addQuadruple(this.conflictFreeContainer, r1, r2, false, null); firePairEvent( new CriticalPairEvent( this, r1, r2, "<" + r1.getName() + "> and <" + r2.getName() + "> should not be computed.")); return; } if (r1.getLayer() != r2.getLayer()) { // test rule layer this.getEntry(r1, r2).state = Entry.NOT_RELATED; addEntry(r1, r2, false, null); addQuadruple(this.excludeContainer, r1, r2, false, null); addQuadruple(this.conflictFreeContainer, r1, r2, false, null); firePairEvent(new CriticalPairEvent(this, r1, r2, "")); return; } if ((this.layer > -1) && (r1.getLayer() != this.layer)) { return; } if ((this.getEntry(r1, r2).state == Entry.SCHEDULED_FOR_COMPUTING) || (this.getEntry(r1, r2).state == Entry.NOT_SET)) { getEntry(r1, r2).setState(Entry.COMPUTING_IS_RUNNING); firePairEvent( new CriticalPairEvent( this, r1, r2, "Computing critical rule pair [ " + r1.getName() + " , " + r2.getName() + " ]")); if (!this.complete) { this.layeredPair = null; this.layeredSimplePair = new LayeredSimpleDependencyPair(); this.excludePair = this.layeredSimplePair; } else { this.layeredSimplePair = null; this.layeredPair = new LayeredDependencyPair(); this.excludePair = this.layeredPair; } setOptionsOfExcludePair(); Vector< Pair< Pair<OrdinaryMorphism, OrdinaryMorphism>, Pair<OrdinaryMorphism, OrdinaryMorphism>>> overlapping = null; try { if (this.layeredPair != null) { overlapping = this.layeredPair.isCritical(CriticalPair.EXCLUDE, r1, r2); } else if (this.layeredSimplePair != null) { overlapping = this.layeredSimplePair.isCritical(CriticalPair.EXCLUDE, r1, r2); } } catch (InvalidAlgorithmException iae) { System.out.println(iae.getLocalizedMessage()); } if (this.excludePair != null) this.excludePair.dispose(); this.excludePair = null; this.layeredPair = null; this.layeredSimplePair = null; // System.gc(); boolean critic = (overlapping != null); // new container addEntry(r1, r2, critic, overlapping); /* * Wenn overlapping Elemente enthaelt sind r1/r2 kritisch critic * wird daher true. Alle wichtigen Informationen werden eingetragen. * Enthaelt r1/r2 keine Elementen, so wird critic auf false gesetzt. * Wenn excludeContainer nach r1/r2 gefragt wird, liefert die * Antwort auch false. overlapping kann daher null sein. */ /* * Achtung, wenn r1 r2 nicht kritisch ist gibt es keine * Ueberlappungen */ addQuadruple(this.excludeContainer, r1, r2, critic, overlapping); /* * conflictfree braucht keine ueberlappungsgraphen daher ist das * letzte Argument null */ addQuadruple(this.conflictFreeContainer, r1, r2, !critic, null); if (overlapping != null) firePairEvent( new CriticalPairEvent( this, r1, r2, "<" + r1.getName() + "> and <" + r2.getName() + "> have critical pairs")); else firePairEvent( new CriticalPairEvent( this, r1, r2, "<" + r1.getName() + "> and <" + r2.getName() + "> have no critical pairs")); } Report.trace("LayeredDependencyPairContainer: beende computeCritical", -2); }
/** * Reads the contents of a xml file to restore this object. * * @param h A helper object for loading. */ public void XreadObject(XMLHelper h) { if (h.isTag("CriticalPairs", this)) { // System.out.println("LayerExcludePairContainer.XreadObject ..."); Rule r1 = null; Rule r2 = null; boolean b = false; Vector< Pair< Pair<OrdinaryMorphism, OrdinaryMorphism>, Pair<OrdinaryMorphism, OrdinaryMorphism>>> allOverlappings = null; Vector<String> tagnames = new Vector<String>(1); Vector<String> tagnames2 = new Vector<String>(1); this.grammar = BaseFactory.theFactory().createGraGra(); h.getObject("", this.grammar, true); tagnames.add("conflictContainer"); tagnames.add("conflictsContainer"); tagnames.add("excludeContainer"); tagnames2.add("dependencyContainer"); tagnames2.add("dependenciesContainer"); this.switchDependency = false; if (h.readSubTag(tagnames2)) { this.conflictKind = CriticalPair.TRIGGER_DEPENDENCY; if (h.readAttr("kind").equals("trigger_switch_dependency")) { this.switchDependency = true; this.conflictKind = CriticalPair.TRIGGER_SWITCH_DEPENDENCY; } } else if (h.readSubTag(tagnames)) { this.conflictKind = CriticalPair.CONFLICT; } if (this.conflictKind == CriticalPair.TRIGGER_DEPENDENCY || this.conflictKind == CriticalPair.TRIGGER_SWITCH_DEPENDENCY || this.conflictKind == CriticalPair.CONFLICT) { Enumeration<?> r1s = h.getEnumeration("", null, true, "Rule"); if (!r1s.hasMoreElements()) r1s = h.getEnumeration("", null, true, "Regel"); while (r1s.hasMoreElements()) { h.peekElement(r1s.nextElement()); /* * da ein referenziertes object geholt werden soll. muss nur * angegeben werden wie der Membername heisst. */ r1 = (Rule) h.getObject("R1", null, false); Enumeration<?> r2s = h.getEnumeration("", null, true, "Rule"); if (!r2s.hasMoreElements()) r2s = h.getEnumeration("", null, true, "Regel"); while (r2s.hasMoreElements()) { h.peekElement(r2s.nextElement()); r2 = (Rule) h.getObject("R2", null, false); String bool = h.readAttr("bool"); allOverlappings = null; b = false; if (bool.equals("true")) { b = true; allOverlappings = new Vector< Pair< Pair<OrdinaryMorphism, OrdinaryMorphism>, Pair<OrdinaryMorphism, OrdinaryMorphism>>>(); Enumeration<?> overlappings = h.getEnumeration("", null, true, "Overlapping_Pair"); while (overlappings.hasMoreElements()) { h.peekElement(overlappings.nextElement()); Graph g = (Graph) h.getObject("", new Graph(), true); while (h.readSubTag("Critical")) { GraphObject o = (GraphObject) h.getObject("object", null, false); if (o != null) o.setCritical(true); h.close(); } /* * OrdinaryMorphism first = * BaseFactory.theFactory().createMorphism(r1.getRight(),g); * first.readMorphism(h); OrdinaryMorphism * second = * BaseFactory.theFactory().createMorphism(r2.getLeft(),g); * second.readMorphism(h); * allOverlappings.addElement(new * Pair(first,second)); */ Pair< Pair<OrdinaryMorphism, OrdinaryMorphism>, Pair<OrdinaryMorphism, OrdinaryMorphism>> p = readOverlappingMorphisms(h, r1, r2, g); allOverlappings.addElement(p); h.close(); } } addQuadruple(this.excludeContainer, r1, r2, b, allOverlappings); h.close(); } h.close(); } h.close(); // System.out.println("excludeContainer // "+excludeContainer+"\n"); } /* Ende readSubTag("excludeContainer") */ if (h.readSubTag("conflictFreeContainer")) { Enumeration<?> r1s = h.getEnumeration("", null, true, "Rule"); if (!r1s.hasMoreElements()) r1s = h.getEnumeration("", null, true, "Regel"); while (r1s.hasMoreElements()) { h.peekElement(r1s.nextElement()); /* * da ein referenziertes object geholt werden soll. muss nur * angegeben werden wie der Membername heisst. */ r1 = (Rule) h.getObject("R1", null, false); Enumeration<?> r2s = h.getEnumeration("", null, true, "Rule"); if (!r2s.hasMoreElements()) r2s = h.getEnumeration("", null, true, "Regel"); while (r2s.hasMoreElements()) { h.peekElement(r2s.nextElement()); r2 = (Rule) h.getObject("R2", null, false); String bool = h.readAttr("bool"); b = false; if (bool.equals("true")) b = true; addQuadruple(this.conflictFreeContainer, r1, r2, b, null); if (!r1.isEnabled()) // test disabled rule this.getEntry(r1, r2).state = Entry.DISABLED; else if (r1.getLayer() != r2.getLayer()) // test rule // layer this.getEntry(r1, r2).state = Entry.NOT_RELATED; h.close(); } h.close(); } h.close(); // System.out.println("conflictFreeContainer // "+conflictFreeContainer+"\n"); } } // isComputed = true; h.close(); }