public static void loadDict(String strDict) { try { BufferedReader br = new BufferedReader(new FileReader(strDict)); String line = null; while ((line = br.readLine()) != null) { int idx = line.indexOf(','); if (idx > 0) { htDict.put(line.substring(0, idx), line.substring(idx + 1)); } } } catch (FileNotFoundException fnfe) { fnfe.printStackTrace(System.out); } catch (IOException ioe) { ioe.printStackTrace(System.out); } }
public static PetriNet convert(ConfigurableEPC baseEPC) { HashMap<EPCFunction, Transition> functionActivityMapping; HashMap<EPCConnector, Place> xorconnectorChoiceMapping; // HV: Initialize the mappings. functionActivityMapping = new HashMap<EPCFunction, Transition>(); xorconnectorChoiceMapping = new HashMap<EPCConnector, Place>(); // Check to use the weights if necessary // HV: Add both mappings. On completion, these will be filledd. PetriNet petrinet = EPCToPetriNetConverter.convert( baseEPC, new HashMap(), functionActivityMapping, xorconnectorChoiceMapping); HashSet visible = new HashSet(); // HV: The next block is taken care of by the functionActivityMapping // below. /* * Iterator it = petrinet.getTransitions().iterator(); while * (it.hasNext()) { Transition t = (Transition) it.next(); if (t.object * instanceof EPCFunction) { // if (t.getLogEvent() != null) { // Add * transitions with LogEvent (i.e. referring to functions) * visible.add(t); } } */ // HV: Prevent the places mapped onto from being reduced. visible.addAll(functionActivityMapping.values()); visible.addAll(xorconnectorChoiceMapping.values()); Message.add(visible.toString(), Message.DEBUG); Iterator it = petrinet.getPlaces().iterator(); while (it.hasNext()) { Place p = (Place) it.next(); if (p.inDegree() * p.outDegree() == 0) { // Add Initial and final places to visible, i.e. places that // refer to in and output events visible.add(p); } } // Reduce the PetriNet with Murata rules, while keeping the visible ones PetriNetReduction pnred = new PetriNetReduction(); pnred.setNonReducableNodes(visible); HashMap pnMap = new HashMap(); // Used to map pre-reduction nodes to // post-reduction nodes. PetriNet reduced = pnred.reduce(petrinet, pnMap); if (reduced != petrinet) { // Update both mappings from pre-reduction nodes to post-reduction // nodes. HashMap<EPCFunction, Transition> newFunctionActivityMapping = new HashMap<EPCFunction, Transition>(); for (EPCFunction function : functionActivityMapping.keySet()) { Transition transition = (Transition) functionActivityMapping.get(function); if (pnMap.keySet().contains(transition)) { newFunctionActivityMapping.put(function, (Transition) pnMap.get(transition)); } } functionActivityMapping = newFunctionActivityMapping; HashMap<EPCConnector, Place> newXorconnectorChoiceMapping = new HashMap<EPCConnector, Place>(); for (EPCConnector connector : xorconnectorChoiceMapping.keySet()) { Place place = (Place) xorconnectorChoiceMapping.get(connector); if (pnMap.keySet().contains(place)) { newXorconnectorChoiceMapping.put(connector, (Place) pnMap.get(place)); } } xorconnectorChoiceMapping = newXorconnectorChoiceMapping; } reduced.makeClusters(); // filter the \nunknown:normal ArrayList<Transition> alTrans = reduced.getVisibleTasks(); for (int i = 0; i < alTrans.size(); i++) { Transition t = alTrans.get(i); String id = t.getIdentifier(); int idx = id.indexOf("\\nunknown:normal"); if (idx > 0) { id = id.substring(0, idx); } // �˴������ֵ��ѯ�滻���е�label String mappedId = htDict.get(id); if (mappedId != null) { t.setIdentifier(mappedId); } else { t.setIdentifier(id); } } return reduced; }