Esempio n. 1
0
  public static String writeGridOfRateCoeffs(ReactionModel p_reactionModel) {

    StringBuilder result = new StringBuilder();

    LinkedList pDepList = new LinkedList();
    CoreEdgeReactionModel cerm = (CoreEdgeReactionModel) p_reactionModel;

    for (Iterator iter = PDepNetwork.getNetworks().iterator(); iter.hasNext(); ) {
      PDepNetwork pdn = (PDepNetwork) iter.next();
      for (ListIterator pdniter = pdn.getNetReactions().listIterator(); pdniter.hasNext(); ) {
        PDepReaction rxn = (PDepReaction) pdniter.next();
        if (cerm.categorizeReaction(rxn) != 1) continue;
        // check if this reaction is not already in the list and also check if this reaction has a
        // reverse reaction
        // which is already present in the list.
        if (rxn.getReverseReaction() == null) rxn.generateReverseReaction();
        if (!rxn.reactantEqualsProduct()
            && !pDepList.contains(rxn)
            && !pDepList.contains(rxn.getReverseReaction())) {
          pDepList.add(rxn);
        }
      }
    }

    Temperature[] tempsUsedInFame = PDepRateConstant.getTemperatures();
    int numTemps = tempsUsedInFame.length;
    Pressure[] pressUsedInFame = PDepRateConstant.getPressures();
    int numPress = pressUsedInFame.length;

    for (int i = 0; i < numTemps; i++) {
      for (int j = 0; j < numPress; j++) {
        result.append(
            "T=" + tempsUsedInFame[i].getK() + "K,P=" + pressUsedInFame[j].getBar() + "bar\t");
      }
      result.append("\n");
    }
    result.append("\n");

    for (Iterator iter = pDepList.iterator(); iter.hasNext(); ) {
      PDepReaction r = (PDepReaction) iter.next();
      result.append(r.toString() + "\n");
      double[][] rates = new double[numTemps][numPress];
      rates = r.getPDepRate().getRateConstants();
      for (int i = 0; i < numTemps; i++) {
        for (int j = 0; j < numPress; j++) {
          result.append(rates[i][j] + "\t");
        }
        result.append("\n");
      }
      result.append("\n");
    }
    return result.toString();
  }
Esempio n. 2
0
 /**
  * Returns the core reactions that are hidden amongst those net reactions which are found in the
  * pressure-dependent networks. This is particularly useful in the initialization of the reaction
  * model, in which the core must have at least one reaction in it before the dynamic simulator can
  * be executed.
  *
  * @param cerm The current core/edge reaction model
  * @return The number of core reactions found
  */
 public static LinkedList<PDepReaction> getCoreReactions(CoreEdgeReactionModel cerm) {
   LinkedList<PDepReaction> coreReactions = new LinkedList<PDepReaction>();
   for (ListIterator<PDepNetwork> iter0 = networks.listIterator(); iter0.hasNext(); ) {
     PDepNetwork pdn = iter0.next();
     for (ListIterator<PDepReaction> iter = pdn.getNetReactions().listIterator();
         iter.hasNext(); ) {
       PDepReaction rxn = iter.next();
       if (rxn.isCoreReaction(cerm) && !coreReactions.contains(rxn)) coreReactions.add(rxn);
     }
   }
   return coreReactions;
 }
Esempio n. 3
0
 /**
  * Useful for debugging, this function prints the isomers of each network to the console window.
  */
 public static void printNetworks() {
   int index = 0;
   for (ListIterator<PDepNetwork> iter0 = networks.listIterator(); iter0.hasNext(); ) {
     PDepNetwork pdn = iter0.next();
     index++;
     System.out.print("Network #" + Integer.toString(index) + ": ");
     for (ListIterator<PDepIsomer> iter = pdn.getIsomers().listIterator(); iter.hasNext(); ) {
       PDepIsomer isomer = iter.next();
       System.out.print(isomer.toString());
       if (iter.hasNext()) System.out.print(", ");
     }
     System.out.print("\n");
   }
 }
Esempio n. 4
0
 // ## operation calculatePDepRate(Temperature)
 public double calculateTotalPDepRate(Temperature p_temperature, Pressure p_pressure) {
   // #[ operation calculatePDepRate(Temperature)
   PDepNetwork pdn = getPDepNetwork();
   if (pdn != null) {
     ListIterator iter = pdn.getNetReactions().listIterator();
     while (iter.hasNext()) {
       PDepReaction pdnr = (PDepReaction) iter.next();
       if (pdnr.getStructure().equals(getStructure()))
         return pdnr.calculateRate(p_temperature, p_pressure);
     }
     iter = pdn.getNonincludedReactions().listIterator();
     while (iter.hasNext()) {
       PDepReaction pdnr = (PDepReaction) iter.next();
       if (pdnr.getStructure().equals(getStructure()))
         return pdnr.calculateRate(p_temperature, p_pressure);
     }
   }
   return calculateTotalRate(p_temperature);
   // #]
 }
Esempio n. 5
0
  // ## operation writeChemkinReactions(ReactionModel)
  public static String writeChemkinPdepReactions(
      ReactionModel p_reactionModel, SystemSnapshot p_beginStatus) {
    // #[ operation writeChemkinReactions(ReactionModel)

    StringBuilder result = new StringBuilder();
    //      result.append("REACTIONS	KCAL/MOLE\n");

    String reactionHeader = "";

    String units4Ea = ArrheniusKinetics.getEaUnits();
    if (units4Ea.equals("cal/mol")) reactionHeader = "CAL/MOL\t";
    else if (units4Ea.equals("kcal/mol")) reactionHeader = "KCAL/MOL\t";
    else if (units4Ea.equals("J/mol")) reactionHeader = "JOULES/MOL\t";
    else if (units4Ea.equals("kJ/mol")) reactionHeader = "KJOULES/MOL\t";
    else if (units4Ea.equals("Kelvins")) reactionHeader = "KELVINS\t";

    String units4A = ArrheniusKinetics.getAUnits();
    if (units4A.equals("moles")) reactionHeader += "MOLES\n";
    else if (units4A.equals("molecules")) reactionHeader += "MOLECULES\n";

    result.append("REACTIONS\t" + reactionHeader);

    LinkedList pDepList = new LinkedList();
    LinkedList nonPDepList = new LinkedList();
    LinkedList duplicates = new LinkedList();

    CoreEdgeReactionModel cerm = (CoreEdgeReactionModel) p_reactionModel;
    // first get troe and thirdbodyreactions
    for (Iterator iter = cerm.getReactionSet().iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();
      /*
       * 1Jul2009-MRH:
       * 	Added extra set of parenthesis.  Before, if the rxn was reverse but an instance of
       * 		TROEReaction, it would also be added to the pDepList, resulting in RMG reporting
       * 		both rxns (forward and reverse) in the chem.inp file, w/o a DUP tag.  Furthermore,
       * 		both rxns were given the same set of Arrhenius parameters.  Running this in
       * 		Chemkin-v4.1.1 resulted in an error.
       */
      if (r.isForward()
          && (r instanceof ThirdBodyReaction
              || r instanceof TROEReaction
              || r instanceof LindemannReaction)) {
        pDepList.add(r);
      }
    }

    for (Iterator iter = PDepNetwork.getNetworks().iterator(); iter.hasNext(); ) {
      PDepNetwork pdn = (PDepNetwork) iter.next();
      for (ListIterator pdniter = pdn.getNetReactions().listIterator(); pdniter.hasNext(); ) {
        PDepReaction rxn = (PDepReaction) pdniter.next();
        if (cerm.categorizeReaction(rxn) != 1) continue;

        // check if this reaction is not already in the list and also check if this reaction has a
        // reverse reaction
        // which is already present in the list.
        if (rxn.getReverseReaction() == null) rxn.generateReverseReaction();

        if (!rxn.reactantEqualsProduct()
            && !pDepList.contains(rxn)
            && !pDepList.contains(rxn.getReverseReaction())) {
          pDepList.add(rxn);
        }
      }
    }
    LinkedList removeReactions = new LinkedList();
    for (Iterator iter = p_reactionModel.getReactionSet().iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();

      boolean presentInPDep = false;
      if (r.isForward()
          && !(r instanceof ThirdBodyReaction)
          && !(r instanceof TROEReaction)
          && !(r instanceof LindemannReaction)) {
        Iterator r_iter = pDepList.iterator();
        while (r_iter.hasNext()) {
          Reaction pDepr = (Reaction) r_iter.next();
          if (pDepr.equals(r)) {
            //      				removeReactions.add(pDepr);
            //      				duplicates.add(pDepr);
            //      				if (!r.hasAdditionalKinetics()){
            //      					duplicates.add(r);
            //      					presentInPDep = true;
            //      				}
            presentInPDep = true;
            nonPDepList.add(r);
          }
        }
        if (!presentInPDep) nonPDepList.add(r);
      }
    }

    for (Iterator iter = removeReactions.iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();
      pDepList.remove(r);
    }

    for (Iterator iter = pDepList.iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();
      // 6Jul2009-MRH:
      //	Pass both system temperature and pressure to function toChemkinString.
      //		The only PDepKineticsModel that uses the passed pressure is RATE
      result.append(
          r.toChemkinString(p_beginStatus.getTemperature(), p_beginStatus.getPressure())
              + "\n"); // 10/26/07 gmagoon: eliminating use of Global.temperature; **** I use
                       // beginStatus here, which may or may not be appropriate
      // result.append(r.toChemkinString(Global.temperature)+"\n");
    }
    for (Iterator iter = nonPDepList.iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();
      result.append(
          r.toChemkinString(p_beginStatus.getTemperature(), p_beginStatus.getPressure()) + "\n");
      // result.append(r.toChemkinString(Global.temperature)+"\n");
    }
    for (Iterator iter = duplicates.iterator(); iter.hasNext(); ) {
      Reaction r = (Reaction) iter.next();
      result.append(
          r.toChemkinString(p_beginStatus.getTemperature(), p_beginStatus.getPressure())
              + "\n\tDUP\n");
      // result.append(r.toChemkinString(Global.temperature)+"\n\tDUP\n");
    }

    result.append("END\n");

    return result.toString();

    // #]
  }
Esempio n. 6
0
  /**
   * Used to add a reaction to the appropriate pressure-dependent network. If no such network
   * exists, a new network is created. For isomerization reactions connecting two existing networks,
   * the networks are merged. This function is to be called whenever a new reaction is added to the
   * edge.
   *
   * @param reaction The reaction to add
   * @return The network the reaction was added to
   */
  public static PDepNetwork addReactionToNetworks(Reaction reaction) {

    // Expect that most reactions passed to this function will be already
    // present in a network

    // Fail if neither reactant nor product are unimolecular
    Species species = null;
    if (reaction.getReactantNumber() == 1) species = (Species) reaction.getReactantList().get(0);
    if (reaction.getProductNumber() == 1) species = (Species) reaction.getProductList().get(0);
    if (species == null) return null;

    if (reaction.getReactantNumber() > 1) reaction = reaction.getReverseReaction();

    PDepNetwork pdn = null;
    if (reaction.getProductNumber() == 1) {
      // Isomerization reactions should cause networks to be merged together
      // This means that each unimolecular isomer should only appear in one network

      // Get the appropriate pressure-dependent network(s)
      PDepNetwork reac_pdn = null;
      PDepNetwork prod_pdn = null;
      Species reactant = (Species) reaction.getReactantList().get(0);
      Species product = (Species) reaction.getProductList().get(0);
      for (ListIterator<PDepNetwork> iter = networks.listIterator(); iter.hasNext(); ) {
        PDepNetwork n = iter.next();
        if (n.contains(reactant)) reac_pdn = n;
        if (n.contains(product)) prod_pdn = n;
      }

      if (reac_pdn != null && prod_pdn != null && reac_pdn != prod_pdn) {
        // Two distinct networks found; must join them together
        pdn = reac_pdn;
        for (int i = 0; i < prod_pdn.getIsomers().size(); i++)
          pdn.addIsomer(prod_pdn.getIsomers().get(i));
        for (int i = 0; i < prod_pdn.getPathReactions().size(); i++)
          pdn.addReaction(prod_pdn.getPathReactions().get(i), false);
        // Also remove the second network from the list of networks
        networks.remove(prod_pdn);
      } else if (reac_pdn != null && prod_pdn != null && reac_pdn == prod_pdn) {
        // Both species already present as unimolecular isomers in the same network, so use that
        // network
        pdn = reac_pdn;
      } else if (reac_pdn != null) {
        // Only reactant species found in a network, so use that network
        pdn = reac_pdn;
      } else if (prod_pdn != null) {
        // Only product species found in a network, so use that network
        pdn = reac_pdn;
      } else {
        // No networks found for either species; will create a new network
        pdn = null;
      }

    } else if (reaction.getProductNumber() > 1) {
      // Dissociation reactions are added to the network containing that unimolecular isomer
      // Since each unimolecular isomer should only appear in one network, there should only be one
      // such addition
      // If no existing network is found, a new one may be created

      // Get the appropriate pressure-dependent network
      Species reactant = (Species) reaction.getReactantList().get(0);
      for (ListIterator<PDepNetwork> iter = networks.listIterator(); iter.hasNext(); ) {
        PDepNetwork n = iter.next();
        if (n.contains(reactant)) pdn = n;
      }
    }

    // If network not found, create a new network
    if (pdn == null) {
      pdn = new PDepNetwork();
      PDepIsomer isomer = new PDepIsomer(species);
      pdn.addIsomer(isomer);
      networks.add(pdn);
    }

    // Add the reaction to the network
    PDepIsomer reactantIsomer = pdn.getIsomer(reaction.getReactantList());
    if (reactantIsomer == null) {
      reactantIsomer = new PDepIsomer(reaction.getReactantList());
      pdn.addIsomer(reactantIsomer);
    }
    PDepIsomer productIsomer = pdn.getIsomer(reaction.getProductList());
    if (productIsomer == null) {
      productIsomer = new PDepIsomer(reaction.getProductList());
      pdn.addIsomer(productIsomer);
    }
    PDepReaction rxn = new PDepReaction(reactantIsomer, productIsomer, reaction);
    pdn.addReaction(rxn, false);

    // Fill in partial network if necessary
    if (reactantIsomer.isCore((CoreEdgeReactionModel) reactionModel)
        && reactantIsomer.isUnimolecular()) pdn.makeIsomerIncluded(reactantIsomer);
    if (productIsomer.isCore((CoreEdgeReactionModel) reactionModel)
        && productIsomer.isUnimolecular()) pdn.makeIsomerIncluded(productIsomer);

    // Return the created network
    return pdn;
  }
 public static void main(String[] args) {
   // Initialize the logger (saves to RMG.log file).
   Logger.initialize();
   initializeSystemProperties();
   try {
     ChemGraph.readForbiddenStructure();
   } catch (IOException e1) {
     System.err.println("PopulateReactions cannot locate forbiddenStructures.txt file");
     e1.printStackTrace();
   }
   ArrheniusKinetics.setAUnits("moles");
   ArrheniusKinetics.setEaUnits("kcal/mol");
   // Creating a new ReactionModelGenerator so I can set the variable temp4BestKinetics
   // and call the new readAndMakePTL and readAndMakePRL methods
   ReactionModelGenerator rmg = new ReactionModelGenerator();
   rmg.setSpeciesSeed(new LinkedHashSet());
   // Set Global.lowTemp and Global.highTemp
   // The values of the low/highTemp are not used in the function
   // (to the best of my knowledge).
   // They are necessary for the instances of additionalKinetics,
   // e.g. H2C*-CH2-CH2-CH3 -> H3C-CH2-*CH-CH3
   /*
    * 7Apr2010: The input file will now ask the user for a TemperatureModel and PressureModel (same as the RMG
    * module). The Global .lowTemperature and .highTemperature will automatically be determined
    */
   // Global.lowTemperature = new Temperature(300,"K");
   // Global.highTemperature = new Temperature(1500,"K");
   // Define variable 'speciesSet' to store the species contained in the input file
   LinkedHashSet speciesSet = new LinkedHashSet();
   // Define variable 'reactions' to store all possible rxns between the species in speciesSet
   LinkedHashSet reactions = new LinkedHashSet();
   // Define two string variables 'listOfReactions' and 'listOfSpecies'
   // These strings will hold the list of rxns (including the structure,
   // modified Arrhenius parameters, and source/comments) and the list of
   // species (including the chemkin name and graph), respectively
   String listOfReactions =
       "Arrhenius 'A' parameter has units of: "
           + ArrheniusEPKinetics.getAUnits()
           + ",cm3,s\n"
           + "Arrhenius 'n' parameter is unitless and assumes Tref = 1K\n"
           + "Arrhenius 'E' parameter has units of: "
           + ArrheniusEPKinetics.getEaUnits()
           + "\n\n";
   String listOfSpecies = "";
   // Open and read the input file
   try {
     FileReader fr_input = new FileReader(args[0]);
     BufferedReader br_input = new BufferedReader(fr_input);
     // Read in the Database field
     String line = ChemParser.readMeaningfulLine(br_input, true);
     if (line.toLowerCase().startsWith("database")) {
       RMG.extractAndSetDatabasePath(line);
     } else {
       System.err.println("PopulateReactions: Could not" + " locate the Database field");
       System.exit(0);
     }
     // Read in the first line of the input file
     // This line should hold the temperature of the system, e.g.
     // Temperature: 500 (K)
     line = ChemParser.readMeaningfulLine(br_input, true);
     /*
      * Read max atom types (if they exist)
      */
     line = rmg.readMaxAtomTypes(line, br_input);
     /*
      * Read primary thermo libraries (if they exist)
      */
     if (line.toLowerCase().startsWith("primarythermolibrary")) {
       rmg.readAndMakePTL(br_input);
     } else {
       System.err.println(
           "PopulateReactions: Could not locate the PrimaryThermoLibrary field.\n"
               + "Line read was: "
               + line);
       System.exit(0);
     }
     line = ChemParser.readMeaningfulLine(br_input, true);
     // Read primary transport library
     if (line.toLowerCase().startsWith("primarytransportlibrary"))
       rmg.readAndMakePTransL(br_input);
     else {
       System.err.println(
           "PopulateReactions: Could not locate the PrimaryTransportLibrary field.\n"
               + "Line read was: "
               + line);
       System.exit(0);
     }
     /*
      * Read the temperature model (must be of length one)
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     rmg.createTModel(line);
     if (rmg.getTempList().size() > 1) {
       System.out.println("Please list only one temperature in the TemperatureModel field.");
       System.exit(0);
     }
     // Set the user's input temperature
     LinkedList tempList = rmg.getTempList();
     systemTemp = ((ConstantTM) tempList.get(0)).getTemperature();
     rmg.setTemp4BestKinetics(systemTemp);
     /*
      * Read the pressure model (must be of length 1)
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     rmg.createPModel(line);
     if (rmg.getPressList().size() > 1) {
       System.out.println("Please list only one pressure in the PressureModel field.");
       System.exit(0);
     }
     /*
      * Read the solvation field (if present)
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     StringTokenizer st = new StringTokenizer(line);
     // The first line should start with "Solvation", otherwise do nothing and display a message to
     // the user
     if (st.nextToken().startsWith("Solvation")) {
       line = st.nextToken().toLowerCase();
       // The options for the "Solvation" field are "on" or "off" (as of 18May2009), otherwise do
       // nothing and
       // display a message to the user
       // Note: I use "Species.useInChI" because the "Species.useSolvation" updates were not yet
       // committed.
       if (line.equals("on")) {
         Species.useSolvation = true;
         // rmg.setUseDiffusion(true);
         listOfReactions += "Solution-phase chemistry!\n\n";
       } else if (line.equals("off")) {
         Species.useSolvation = false;
         // rmg.setUseDiffusion(false);
         listOfReactions += "Gas-phase chemistry.\n\n";
       } else {
         System.out.println(
             "Error in reading input.txt file:\nThe field 'Solvation' has the options 'on' or 'off'."
                 + "\nPopulateReactions does not recognize: "
                 + line);
         return;
       }
       line = ChemParser.readMeaningfulLine(br_input, true);
     }
     /*
      * Read in the species (name, concentration, adjacency list)
      */
     if (line.toLowerCase().startsWith("speciesstatus")) {
       LinkedHashMap lhm = new LinkedHashMap();
       lhm = rmg.populateInitialStatusListWithReactiveSpecies(br_input);
       speciesSet.addAll(lhm.values());
     }
     /*
      * Read in the inert gas (name, concentration)
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     if (line.toLowerCase().startsWith("bathgas")) {
       rmg.populateInitialStatusListWithInertSpecies(br_input);
     }
     /*
      * Read in the p-dep options
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     if (line.toLowerCase().startsWith("spectroscopicdata")) {
       rmg.setSpectroscopicDataMode(line);
       line = ChemParser.readMeaningfulLine(br_input, true);
       line = rmg.setPressureDependenceOptions(line, br_input);
     }
     /*
      * Read primary kinetic libraries (if they exist)
      */
     if (line.toLowerCase().startsWith("primarykineticlibrary")) {
       rmg.readAndMakePKL(br_input);
     } else {
       System.err.println(
           "PopulateReactions: Could not locate the PrimaryKineticLibrary field."
               + "Line read was: "
               + line);
       System.exit(0);
     }
     line = ChemParser.readMeaningfulLine(br_input, true);
     if (line.toLowerCase().startsWith("reactionlibrary")) {
       rmg.readAndMakeReactionLibrary(br_input);
     } else {
       System.err.println(
           "PopulateReactions: Could not locate the ReactionLibrary field."
               + "Line read was: "
               + line);
       System.exit(0);
     }
     /*
      * Read in verbosity field (if it exists)
      */
     line = ChemParser.readMeaningfulLine(br_input, true);
     if (line != null && line.toLowerCase().startsWith("verbose")) {
       StringTokenizer st2 = new StringTokenizer(line);
       String tempString = st2.nextToken();
       tempString = st2.nextToken();
       tempString = tempString.toLowerCase();
       if (tempString.equals("on") || tempString.equals("true") || tempString.equals("yes"))
         ArrheniusKinetics.setVerbose(true);
     }
     TemplateReactionGenerator rtLibrary = new TemplateReactionGenerator();
     // / THE SERVERY BIT
     ServerSocket Server = new ServerSocket(5000);
     Logger.info("TCPServer Waiting for client on port 5000");
     Logger.info("Switching to quiet mode - only WARNINGS and above will be logged...");
     Logger.setConsoleLevel(jing.rxnSys.Logger.WARNING);
     Logger.setFileLevel(jing.rxnSys.Logger.WARNING);
     while (true) {
       Socket connected = Server.accept();
       Logger.warning(
           " THE CLIENT"
               + " "
               + connected.getInetAddress()
               + ":"
               + connected.getPort()
               + " IS CONNECTED ");
       BufferedReader inFromClient =
           new BufferedReader(new InputStreamReader(connected.getInputStream()));
       inFromClient.mark(4096); // so you can reset up to 4096 characters back.
       PrintWriter outToClient = new PrintWriter(connected.getOutputStream(), true);
       try {
         listOfReactions =
             "Arrhenius 'A' parameter has units of: "
                 + ArrheniusEPKinetics.getAUnits()
                 + ",cm3,s\n"
                 + "Arrhenius 'n' parameter is unitless and assumes Tref = 1K\n"
                 + "Arrhenius 'E' parameter has units of: "
                 + ArrheniusEPKinetics.getEaUnits()
                 + "\n\n";
         listOfSpecies = "";
         // clear old things
         speciesSet.clear();
         reactions.clear();
         /*
          * Read in the species (name, concentration, adjacency list)
          */
         LinkedHashMap lhm = new LinkedHashMap();
         lhm = rmg.populateInitialStatusListWithReactiveSpecies(inFromClient);
         speciesSet.addAll(lhm.values());
         // Check Reaction Library
         ReactionLibrary RL = rmg.getReactionLibrary();
         LibraryReactionGenerator lrg1 = new LibraryReactionGenerator(RL);
         reactions = lrg1.react(speciesSet);
         if (RL != null) {
           System.out.println("Checking Reaction Library " + RL.getName() + " for reactions.");
           Iterator ReactionIter = reactions.iterator();
           while (ReactionIter.hasNext()) {
             Reaction current_reaction = (Reaction) ReactionIter.next();
             System.out.println("Library Reaction: " + current_reaction.toString());
           }
         }
         // Add all reactions found from RMG template reaction generator
         reactions.addAll(rtLibrary.react(speciesSet));
         System.out.println("FINISHED generating template reactions");
         if (!(rmg.getReactionModelEnlarger() instanceof RateBasedRME)) {
           // NOT an instance of RateBasedRME therefore assume RateBasedPDepRME and we're doing
           // pressure
           // dependence
           CoreEdgeReactionModel cerm = new CoreEdgeReactionModel(speciesSet, reactions);
           rmg.setReactionModel(cerm);
           rmg.setReactionGenerator(rtLibrary);
           ReactionSystem rs =
               new ReactionSystem(
                   (TemperatureModel) rmg.getTempList().get(0),
                   (PressureModel) rmg.getPressList().get(0),
                   rmg.getReactionModelEnlarger(),
                   new FinishController(),
                   null,
                   rmg.getPrimaryKineticLibrary(),
                   rmg.getReactionGenerator(),
                   speciesSet,
                   (InitialStatus) rmg.getInitialStatusList().get(0),
                   rmg.getReactionModel(),
                   rmg.getLibraryReactionGenerator(),
                   0,
                   "GasPhase");
           PDepNetwork.reactionModel = rmg.getReactionModel();
           PDepNetwork.reactionSystem = rs;
           // If the reaction structure is A + B = C + D, we are not concerned w/pdep
           Iterator iter = reactions.iterator();
           LinkedHashSet nonPdepReactions = new LinkedHashSet();
           while (iter.hasNext()) {
             Reaction r = (Reaction) iter.next();
             if (FastMasterEqn.isReactionPressureDependent(r)) {
               cerm.categorizeReaction(r.getStructure());
               PDepNetwork.addReactionToNetworks(r);
             } else {
               nonPdepReactions.add(r);
             }
           }
           // Run fame calculation
           PDepKineticsEstimator pDepKineticsEstimator =
               ((RateBasedPDepRME) rmg.getReactionModelEnlarger()).getPDepKineticsEstimator();
           BathGas bathGas = new BathGas(rs);
           for (int numNetworks = 0;
               numNetworks < PDepNetwork.getNetworks().size();
               ++numNetworks) {
             LinkedHashSet allSpeciesInNetwork = new LinkedHashSet();
             PDepNetwork pdepnetwork = PDepNetwork.getNetworks().get(numNetworks);
             LinkedList isomers = pdepnetwork.getIsomers();
             for (int numIsomers = 0; numIsomers < isomers.size(); ++numIsomers) {
               PDepIsomer currentIsomer = (PDepIsomer) isomers.get(numIsomers);
               if (currentIsomer.getNumSpecies() == 2)
                 pdepnetwork.makeIsomerIncluded(currentIsomer);
             }
             pDepKineticsEstimator.runPDepCalculation(pdepnetwork, rs, cerm);
             if (pdepnetwork.getNetReactions().size() > 0) {
               String formatSpeciesName = "%1$-16s\t";
               listOfReactions +=
                   "!PDepNetwork\n"
                       + "!\tdeltaEdown = "
                       + bathGas.getDeltaEdown().getAlpha()
                       + "(T / "
                       + bathGas.getDeltaEdown().getT0()
                       + ")^"
                       + bathGas.getDeltaEdown().getN()
                       + " kJ/mol\n"
                       + "!\tbathgas MW = "
                       + bathGas.getMolecularWeight()
                       + " amu\n"
                       + "!\tbathgas LJ sigma = "
                       + bathGas.getLJSigma()
                       + " meters\n"
                       + "!\tbathgas LJ epsilon = "
                       + bathGas.getLJEpsilon()
                       + " Joules\n"
                       + "!Here are the species and their thermochemistry:\n";
               LinkedList<PDepIsomer> allpdepisomers = pdepnetwork.getIsomers();
               for (int numIsomers = 0; numIsomers < allpdepisomers.size(); ++numIsomers) {
                 LinkedList species = allpdepisomers.get(numIsomers).getSpeciesList();
                 for (int numSpecies = 0; numSpecies < species.size(); ++numSpecies) {
                   Species currentSpec = (Species) species.get(numSpecies);
                   if (!allSpeciesInNetwork.contains(currentSpec)) {
                     listOfReactions +=
                         "!\t"
                             + String.format(formatSpeciesName, currentSpec.getFullName())
                             + currentSpec.getThermoData().toString()
                             + currentSpec.getThermoData().getSource()
                             + "\n";
                     allSpeciesInNetwork.add(currentSpec);
                   }
                 }
                 speciesSet.addAll(species);
               }
               String formatRxnName = "%1$-32s\t";
               listOfReactions +=
                   "!Here are the path reactions and their high-P limit kinetics:\n";
               LinkedList<PDepReaction> pathRxns = pdepnetwork.getPathReactions();
               for (int numPathRxns = 0; numPathRxns < pathRxns.size(); numPathRxns++) {
                 Kinetics[] currentKinetics = pathRxns.get(numPathRxns).getKinetics();
                 for (int numKinetics = 0; numKinetics < currentKinetics.length; ++numKinetics) {
                   listOfReactions +=
                       "!\t"
                           + String.format(
                               formatRxnName,
                               pathRxns.get(numPathRxns).getStructure().toRestartString(true))
                           + currentKinetics[numKinetics].toChemkinString(
                               pathRxns
                                   .get(numPathRxns)
                                   .calculateHrxn(new Temperature(298.0, "K")),
                               new Temperature(298.0, "K"),
                               false)
                           + "\n";
                 }
               }
               listOfReactions += "\n";
               LinkedList<PDepReaction> indivPDepRxns = pdepnetwork.getNetReactions();
               for (int numPDepRxns = 0; numPDepRxns < indivPDepRxns.size(); numPDepRxns++) {
                 listOfReactions += indivPDepRxns.get(numPDepRxns).toRestartString(systemTemp);
               }
               LinkedList<PDepReaction> nonIncludedRxns = pdepnetwork.getNonincludedReactions();
               for (int numNonRxns = 0; numNonRxns < nonIncludedRxns.size(); ++numNonRxns) {
                 listOfReactions += nonIncludedRxns.get(numNonRxns).toRestartString(systemTemp);
               }
             }
           }
           reactions = nonPdepReactions;
         }
         // Some of the reactions may be duplicates of one another
         // (e.g. H+CH4=CH3+H2 as a forward reaction and reverse reaction)
         // Create new LinkedHashSet which will store the non-duplicate rxns
         LinkedHashSet nonDuplicateRxns = new LinkedHashSet();
         int Counter = 0;
         Iterator iter_rxns = reactions.iterator();
         while (iter_rxns.hasNext()) {
           ++Counter;
           Reaction r = (Reaction) iter_rxns.next();
           // The first reaction is not a duplicate of any previous reaction
           if (Counter == 1) {
             nonDuplicateRxns.add(r);
             listOfReactions += writeOutputString(r, rtLibrary);
             speciesSet.addAll(r.getProductList());
           }
           // Check whether the current reaction (or its reverse) has the same structure
           // of any reactions already reported in the output
           else {
             Iterator iterOverNonDup = nonDuplicateRxns.iterator();
             boolean dupRxn = false;
             while (iterOverNonDup.hasNext()) {
               Reaction temp_Reaction = (Reaction) iterOverNonDup.next();
               if (r.getStructure() == temp_Reaction.getStructure()) {
                 dupRxn = true;
                 break;
               } else if (r.hasReverseReaction()) {
                 if (r.getReverseReaction().getStructure() == temp_Reaction.getStructure()) {
                   dupRxn = true;
                   break;
                 }
               }
             }
             if (!dupRxn) {
               nonDuplicateRxns.add(r);
               // If Reaction is Not a Library Reaction
               listOfReactions += writeOutputString(r, rtLibrary);
               speciesSet.addAll(r.getProductList());
             }
           }
         }
         Iterator iter_species = speciesSet.iterator();
         // Define dummy integer 'i' so our getChemGraph().toString()
         // call only returns the graph
         int i = 0;
         while (iter_species.hasNext()) {
           Species species = (Species) iter_species.next();
           listOfSpecies +=
               species.getFullName() + "\n" + species.getChemGraph().toStringWithoutH(i) + "\n";
         }
         // Write the output files
         try {
           File rxns = new File("PopRxnsOutput_rxns.txt");
           FileWriter fw_rxns = new FileWriter(rxns);
           fw_rxns.write(listOfReactions);
           fw_rxns.close();
           File spcs = new File("PopRxnsOutput_spcs.txt");
           FileWriter fw_spcs = new FileWriter(spcs);
           fw_spcs.write(listOfSpecies);
           fw_spcs.close();
         } catch (IOException e) {
           System.err.println("Could not write PopRxnsOutput*.txt files");
         }
         // Display to the user that the program was successful and also
         // inform them where the results may be located
         System.out.println(
             "Reaction population complete. "
                 + "Results are stored in PopRxnsOutput_rxns.txt and PopRxnsOutput_spcs.txt");
         // send output to client
         System.out.println("SENDING RESPONSE TO CLIENT");
         outToClient.println(listOfSpecies);
         outToClient.println(listOfReactions);
       } catch (Throwable t) {
         Logger.error("Error in PopulateReactionsServer");
         try {
           inFromClient.reset();
           Logger.error("Input:");
           while (inFromClient.ready()) {
             Logger.error(inFromClient.readLine());
           }
         } catch (IOException e) {
           Logger.error("Couldn't read input stream");
         }
         Logger.logStackTrace(t);
         outToClient.println("Error in PopulateReactionsServer");
         t.printStackTrace(outToClient);
       }
       connected.close();
       System.out.println("SOCKET CLOSED");
     }
   } catch (FileNotFoundException e) {
     System.err.println("File was not found!\n");
   } catch (IOException e) {
     System.err.println(
         "IOException: Something maybe wrong with ChemParser.readChemGraph.\n" + e.toString());
   }
 }