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Example 1 with ParticleInitialConditionCount

use of cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount in project vcell by virtualcell.

the class NFsimXMLWriter method getListOfSpecies.

private static Element getListOfSpecies(MathDescription mathDesc, SimulationSymbolTable simulationSymbolTable) throws SolverException {
    CompartmentSubDomain compartmentSubDomain = (CompartmentSubDomain) mathDesc.getSubDomains().nextElement();
    // 
    // NFsim expects a list of seed species.  These are concrete species patterns that have a "ParticleProperties" element defined (for initial conditions).
    // 
    Element listOfSpeciesElement = new Element("ListOfSpecies");
    for (int speciesIndex = 0; speciesIndex < compartmentSubDomain.getParticleProperties().size(); speciesIndex++) {
        // seedSpecies.getSpeciesPattern().resolveBonds();
        ParticleProperties particleProperties = compartmentSubDomain.getParticleProperties().get(speciesIndex);
        Element speciesElement = new Element("Species");
        String speciesID = "S" + (speciesIndex + 1);
        ParticleSpeciesPattern seedSpecies = (ParticleSpeciesPattern) particleProperties.getVariable();
        speciesElement.setAttribute("id", speciesID);
        speciesElement.setAttribute("name", seedSpecies.getName());
        List<ParticleInitialCondition> particleInitialConditions = particleProperties.getParticleInitialConditions();
        if (particleInitialConditions.size() != 1) {
            throw new SolverException("multiple particle initial conditions not expected for " + ParticleSpeciesPattern.class.getSimpleName() + " " + seedSpecies.getName());
        }
        // the initial conditions must be a count in math (ParticleInitialConditionCount)
        if (!(particleInitialConditions.get(0) instanceof ParticleInitialConditionCount)) {
            throw new SolverException("expecting initial count for " + ParticleSpeciesPattern.class.getSimpleName() + " " + seedSpecies.getName());
        }
        ParticleInitialConditionCount initialCount = (ParticleInitialConditionCount) particleInitialConditions.get(0);
        try {
            double value = evaluateConstant(initialCount.getCount(), simulationSymbolTable);
            Integer maxMoleculesPerType = simulationSymbolTable.getSimulation().getSolverTaskDescription().getNFSimSimulationOptions().getMaxMoleculesPerType();
            if (maxMoleculesPerType == null) {
                maxMoleculesPerType = NFsimSimulationOptions.DefaultMaxMoleculesPerSpecies;
            }
            if (maxMoleculesPerType.doubleValue() < value) {
                String eMessage = "The Initial count for Species '" + seedSpecies.getName() + "' is " + BigDecimal.valueOf(value).toBigInteger();
                eMessage += ", which is higher than the limit of " + maxMoleculesPerType + ".\n";
                eMessage += "Please do one of the following: \n- reduce the Initial Condition value for this Species or reduce the compartment size\n";
                eMessage += "- increase the maximal number of Molecules per Molecular Type in the Advanced Solver Options panel.";
                throw new RuntimeException(eMessage);
            }
            speciesElement.setAttribute("concentration", Double.toString(value));
        } catch (ExpressionException | MathException e) {
            e.printStackTrace();
            throw new SolverException("error processing initial count of " + ParticleSpeciesPattern.class.getSimpleName() + " " + seedSpecies.getName() + ": " + e.getMessage());
        }
        HashMap<Bond, BondSites> bondSiteMapping = new HashMap<Bond, BondSites>();
        Element listOfMoleculesElement = getListOfMolecules(speciesID, seedSpecies, bondSiteMapping);
        speciesElement.addContent(listOfMoleculesElement);
        if (bondSiteMapping.size() > 0) {
            Element listOfBondsElement = getListOfBonds(bondSiteMapping);
            speciesElement.addContent(listOfBondsElement);
        }
        listOfSpeciesElement.addContent(speciesElement);
    }
    return listOfSpeciesElement;
}
Also used : HashMap(java.util.HashMap) Element(org.jdom.Element) ExpressionException(cbit.vcell.parser.ExpressionException) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) ParticleInitialCondition(cbit.vcell.math.ParticleProperties.ParticleInitialCondition) MathException(cbit.vcell.math.MathException) ParticleProperties(cbit.vcell.math.ParticleProperties) ParticleSpeciesPattern(cbit.vcell.math.ParticleSpeciesPattern) VolumeParticleSpeciesPattern(cbit.vcell.math.VolumeParticleSpeciesPattern) SolverException(cbit.vcell.solver.SolverException) ParticleInitialConditionCount(cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)

Example 2 with ParticleInitialConditionCount

use of cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount in project vcell by virtualcell.

the class SmoldynFileWriter method writeMolecules.

private void writeMolecules() throws ExpressionException, MathException {
    // write molecules
    StringBuilder sb = new StringBuilder();
    int max_mol = 0;
    Enumeration<SubDomain> subDomainEnumeration = mathDesc.getSubDomains();
    while (subDomainEnumeration.hasMoreElements()) {
        SubDomain subDomain = subDomainEnumeration.nextElement();
        for (ParticleProperties particleProperties : subDomain.getParticleProperties()) {
            ArrayList<ParticleInitialCondition> particleInitialConditions = particleProperties.getParticleInitialConditions();
            String variableName = getVariableName(particleProperties.getVariable(), subDomain);
            for (ParticleInitialCondition pic : particleInitialConditions) {
                if (pic instanceof ParticleInitialConditionCount) {
                    max_mol += writeInitialCount((ParticleInitialConditionCount) pic, subDomain, variableName, sb);
                } else if (pic instanceof ParticleInitialConditionConcentration) {
                    max_mol += writeInitialConcentration((ParticleInitialConditionConcentration) pic, subDomain, particleProperties.getVariable(), variableName, sb);
                }
            }
            if (lg.isDebugEnabled()) {
                lg.debug("subdomain " + subDomain.getName() + ' ' + variableName + " processed, maximum mol estimate now " + max_mol);
            }
        }
    }
    if (max_mol > MAX_MOLECULE_LIMIT) {
        throw new MathException(VCellErrorMessages.getSmoldynMaxMolReachedErrorMessage((long) max_mol, MAX_MOLECULE_LIMIT));
    }
    int max_adjusted = max_mol * MOLECULE_MAX_COEFFICIENT;
    if (max_adjusted < MIN_MOLECULE_LIMIT) {
        if (lg.isInfoEnabled()) {
            lg.info("adjusting computed max " + max_adjusted + " to minimum " + MIN_MOLECULE_LIMIT);
        }
        max_adjusted = MIN_MOLECULE_LIMIT;
    }
    if (max_adjusted > MAX_MOLECULE_LIMIT) {
        if (lg.isInfoEnabled()) {
            lg.info("adjusting computed max " + max_adjusted + " to maximum " + MAX_MOLECULE_LIMIT);
        }
        max_adjusted = MAX_MOLECULE_LIMIT;
    }
    printWriter.println("# molecules");
    printWriter.println(SmoldynVCellMapper.SmoldynKeyword.max_mol + " " + max_adjusted);
    printWriter.println(sb);
}
Also used : CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) SubDomain(cbit.vcell.math.SubDomain) MembraneSubDomain(cbit.vcell.math.MembraneSubDomain) ParticleInitialConditionConcentration(cbit.vcell.math.ParticleProperties.ParticleInitialConditionConcentration) ParticleInitialCondition(cbit.vcell.math.ParticleProperties.ParticleInitialCondition) MathException(cbit.vcell.math.MathException) ParticleProperties(cbit.vcell.math.ParticleProperties) ParticleInitialConditionCount(cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)

Example 3 with ParticleInitialConditionCount

use of cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount in project vcell by virtualcell.

the class XmlReader method getParticleInitialConditionCount.

private ParticleInitialConditionCount getParticleInitialConditionCount(Element param) {
    String temp = param.getChildText(XMLTags.ParticleCountTag, vcNamespace);
    Expression countExp = null;
    if (temp != null && temp.length() > 0) {
        countExp = unMangleExpression(temp);
    }
    temp = param.getChildText(XMLTags.ParticleLocationXTag, vcNamespace);
    Expression locXExp = null;
    if (temp != null && temp.length() > 0) {
        locXExp = unMangleExpression(temp);
    }
    temp = param.getChildText(XMLTags.ParticleLocationYTag, vcNamespace);
    Expression locYExp = null;
    if (temp != null && temp.length() > 0) {
        locYExp = unMangleExpression(temp);
    }
    temp = param.getChildText(XMLTags.ParticleLocationZTag, vcNamespace);
    Expression locZExp = null;
    if (temp != null && temp.length() > 0) {
        locZExp = unMangleExpression(temp);
    }
    return new ParticleInitialConditionCount(countExp, locXExp, locYExp, locZExp);
}
Also used : Expression(cbit.vcell.parser.Expression) ParticleInitialConditionCount(cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)

Example 4 with ParticleInitialConditionCount

use of cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount in project vcell by virtualcell.

the class ParticleMathMapping method refreshMathDescription.

/**
 * This method was created in VisualAge.
 */
private void refreshMathDescription() throws MappingException, MatrixException, MathException, ExpressionException, ModelException {
    getSimulationContext().checkValidity();
    if (getSimulationContext().getGeometry().getDimension() == 0) {
        throw new MappingException("particle math mapping requires spatial geometry - dimension >= 1");
    }
    StructureMapping[] structureMappings = getSimulationContext().getGeometryContext().getStructureMappings();
    for (int i = 0; i < structureMappings.length; i++) {
        if (structureMappings[i] instanceof MembraneMapping) {
            if (((MembraneMapping) structureMappings[i]).getCalculateVoltage()) {
                throw new MappingException("electric potential not yet supported for particle models");
            }
        }
    }
    // 
    // fail if any events
    // 
    BioEvent[] bioEvents = getSimulationContext().getBioEvents();
    if (bioEvents != null && bioEvents.length > 0) {
        throw new MappingException("events not yet supported for particle-based models");
    }
    // 
    // gather only those reactionSteps that are not "excluded"
    // 
    ReactionSpec[] reactionSpecs = getSimulationContext().getReactionContext().getReactionSpecs();
    Vector<ReactionStep> rsList = new Vector<ReactionStep>();
    for (int i = 0; i < reactionSpecs.length; i++) {
        if (reactionSpecs[i].isExcluded() == false) {
            if (reactionSpecs[i].isFast()) {
                throw new MappingException("fast reactions not supported for particle models");
            }
            rsList.add(reactionSpecs[i].getReactionStep());
        }
    }
    ReactionStep[] reactionSteps = new ReactionStep[rsList.size()];
    rsList.copyInto(reactionSteps);
    // 
    for (int i = 0; i < reactionSteps.length; i++) {
        Kinetics.UnresolvedParameter[] unresolvedParameters = reactionSteps[i].getKinetics().getUnresolvedParameters();
        if (unresolvedParameters != null && unresolvedParameters.length > 0) {
            StringBuffer buffer = new StringBuffer();
            for (int j = 0; j < unresolvedParameters.length; j++) {
                if (j > 0) {
                    buffer.append(", ");
                }
                buffer.append(unresolvedParameters[j].getName());
            }
            throw new MappingException(reactionSteps[i].getDisplayType() + " '" + reactionSteps[i].getName() + "' contains unresolved identifier(s): " + buffer);
        }
    }
    // 
    // temporarily place all variables in a hashtable (before binding) and discarding duplicates (check for equality)
    // 
    VariableHash varHash = new VariableHash();
    // //
    // // verify that all structures are mapped to geometry classes and all geometry classes are mapped to a structure
    // //
    // Structure structures[] = getSimulationContext().getGeometryContext().getModel().getStructures();
    // for (int i = 0; i < structures.length; i++){
    // StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(structures[i]);
    // if (sm==null || (sm.getGeometryClass() == null)){
    // throw new MappingException("model structure '"+structures[i].getName()+"' not mapped to a geometry subdomain");
    // }
    // if (sm.getUnitSizeParameter()!=null){
    // Expression unitSizeExp = sm.getUnitSizeParameter().getExpression();
    // if(unitSizeExp != null)
    // {
    // try {
    // double unitSize = unitSizeExp.evaluateConstant();
    // if (unitSize != 1.0){
    // throw new MappingException("model structure '"+sm.getStructure().getName()+"' unit size = "+unitSize+" != 1.0 ... partial volume or surface mapping not yet supported for particles");
    // }
    // }catch (ExpressionException e){
    // e.printStackTrace(System.out);
    // throw new MappingException("couldn't evaluate unit size for model structure '"+sm.getStructure().getName()+"' : "+e.getMessage());
    // }
    // }
    // }
    // }
    // {
    // GeometryClass[] geometryClass = getSimulationContext().getGeometryContext().getGeometry().getGeometryClasses();
    // for (int i = 0; i < geometryClass.length; i++){
    // Structure[] mappedStructures = getSimulationContext().getGeometryContext().getStructuresFromGeometryClass(geometryClass[i]);
    // if (mappedStructures==null || mappedStructures.length==0){
    // throw new MappingException("geometryClass '"+geometryClass[i].getName()+"' not mapped from a model structure");
    // }
    // }
    // }
    // deals with model parameters
    Model model = getSimulationContext().getModel();
    ModelUnitSystem modelUnitSystem = model.getUnitSystem();
    ModelParameter[] modelParameters = model.getModelParameters();
    // populate in globalParameterVariants hashtable
    for (int j = 0; j < modelParameters.length; j++) {
        Expression modelParamExpr = modelParameters[j].getExpression();
        GeometryClass geometryClass = getDefaultGeometryClass(modelParamExpr);
        modelParamExpr = getIdentifierSubstitutions(modelParamExpr, modelParameters[j].getUnitDefinition(), geometryClass);
        varHash.addVariable(newFunctionOrConstant(getMathSymbol(modelParameters[j], geometryClass), modelParamExpr, geometryClass));
    }
    // 
    // create new MathDescription (based on simContext's previous MathDescription if possible)
    // 
    MathDescription oldMathDesc = getSimulationContext().getMathDescription();
    mathDesc = null;
    if (oldMathDesc != null) {
        if (oldMathDesc.getVersion() != null) {
            mathDesc = new MathDescription(oldMathDesc.getVersion());
        } else {
            mathDesc = new MathDescription(oldMathDesc.getName());
        }
    } else {
        mathDesc = new MathDescription(getSimulationContext().getName() + "_generated");
    }
    // 
    // volume particle variables
    // 
    Enumeration<SpeciesContextMapping> enum1 = getSpeciesContextMappings();
    while (enum1.hasMoreElements()) {
        SpeciesContextMapping scm = enum1.nextElement();
        if (scm.getVariable() instanceof ParticleVariable) {
            if (!(mathDesc.getVariable(scm.getVariable().getName()) instanceof ParticleVariable)) {
                varHash.addVariable(scm.getVariable());
            }
        }
    }
    varHash.addVariable(new Constant(getMathSymbol(model.getPI_CONSTANT(), null), getIdentifierSubstitutions(model.getPI_CONSTANT().getExpression(), model.getPI_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getFARADAY_CONSTANT(), null), getIdentifierSubstitutions(model.getFARADAY_CONSTANT().getExpression(), model.getFARADAY_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getFARADAY_CONSTANT_NMOLE(), null), getIdentifierSubstitutions(model.getFARADAY_CONSTANT_NMOLE().getExpression(), model.getFARADAY_CONSTANT_NMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getGAS_CONSTANT(), null), getIdentifierSubstitutions(model.getGAS_CONSTANT().getExpression(), model.getGAS_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getTEMPERATURE(), null), getIdentifierSubstitutions(new Expression(getSimulationContext().getTemperatureKelvin()), model.getTEMPERATURE().getUnitDefinition(), null)));
    // 
    for (int j = 0; j < structureMappings.length; j++) {
        if (structureMappings[j] instanceof MembraneMapping) {
            MembraneMapping membraneMapping = (MembraneMapping) structureMappings[j];
            GeometryClass geometryClass = membraneMapping.getGeometryClass();
            // 
            // don't calculate voltage, still may need it though
            // 
            Parameter initialVoltageParm = membraneMapping.getInitialVoltageParameter();
            Variable voltageFunction = newFunctionOrConstant(getMathSymbol(membraneMapping.getMembrane().getMembraneVoltage(), geometryClass), getIdentifierSubstitutions(initialVoltageParm.getExpression(), initialVoltageParm.getUnitDefinition(), geometryClass), geometryClass);
            varHash.addVariable(voltageFunction);
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(membraneMapping.getMembrane().getMembraneVoltage(), membraneMapping.getGeometryClass()), getIdentifierSubstitutions(membraneMapping.getInitialVoltageParameter().getExpression(), membraneMapping.getInitialVoltageParameter().getUnitDefinition(), membraneMapping.getGeometryClass()), membraneMapping.getGeometryClass()));
        }
    }
    // 
    for (int j = 0; j < reactionSteps.length; j++) {
        ReactionStep rs = reactionSteps[j];
        if (getSimulationContext().getReactionContext().getReactionSpec(rs).isExcluded()) {
            continue;
        }
        Kinetics.KineticsParameter[] parameters = rs.getKinetics().getKineticsParameters();
        GeometryClass geometryClass = null;
        if (rs.getStructure() != null) {
            geometryClass = getSimulationContext().getGeometryContext().getStructureMapping(rs.getStructure()).getGeometryClass();
        }
        if (parameters != null) {
            for (int i = 0; i < parameters.length; i++) {
                // Reaction rate, currentDensity, LumpedCurrent and null parameters are not going to displayed in the particle math description.
                if (((parameters[i].getRole() == Kinetics.ROLE_CurrentDensity) || (parameters[i].getRole() == Kinetics.ROLE_LumpedCurrent) || (parameters[i].getRole() == Kinetics.ROLE_ReactionRate)) || (parameters[i].getExpression() == null)) {
                    continue;
                }
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(parameters[i], geometryClass), getIdentifierSubstitutions(parameters[i].getExpression(), parameters[i].getUnitDefinition(), geometryClass), geometryClass));
            }
        }
    }
    // 
    // initial constants (either function or constant)
    // 
    SpeciesContextSpec[] speciesContextSpecs = getSimulationContext().getReactionContext().getSpeciesContextSpecs();
    for (int i = 0; i < speciesContextSpecs.length; i++) {
        SpeciesContextSpecParameter initParm = null;
        Expression initExpr = null;
        if (getSimulationContext().isUsingConcentration()) {
            initParm = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_InitialConcentration);
            initExpr = new Expression(initParm.getExpression());
        // if (speciesContextSpecs[i].getSpeciesContext().getStructure() instanceof Feature) {
        // initExpr = Expression.div(initExpr, new Expression(model.getKMOLE, getNameScope())).flatten();
        // }
        } else {
            initParm = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_InitialCount);
            initExpr = new Expression(initParm.getExpression());
        }
        if (initExpr != null) {
            StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(speciesContextSpecs[i].getSpeciesContext().getStructure());
            String[] symbols = initExpr.getSymbols();
            // Check if 'initExpr' has other speciesContexts in its expression, need to replace it with 'spContext_init'
            for (int j = 0; symbols != null && j < symbols.length; j++) {
                // if symbol is a speciesContext, replacing it with a reference to initial condition for that speciesContext.
                SpeciesContext spC = null;
                SymbolTableEntry ste = initExpr.getSymbolBinding(symbols[j]);
                if (ste instanceof SpeciesContextSpecProxyParameter) {
                    SpeciesContextSpecProxyParameter spspp = (SpeciesContextSpecProxyParameter) ste;
                    if (spspp.getTarget() instanceof SpeciesContext) {
                        spC = (SpeciesContext) spspp.getTarget();
                        SpeciesContextSpec spcspec = getSimulationContext().getReactionContext().getSpeciesContextSpec(spC);
                        SpeciesContextSpecParameter spCInitParm = spcspec.getParameterFromRole(SpeciesContextSpec.ROLE_InitialConcentration);
                        // if initConc param expression is null, try initCount
                        if (spCInitParm.getExpression() == null) {
                            spCInitParm = spcspec.getParameterFromRole(SpeciesContextSpec.ROLE_InitialCount);
                        }
                        // need to get init condn expression, but can't get it from getMathSymbol() (mapping between bio and math), hence get it as below.
                        Expression scsInitExpr = new Expression(spCInitParm, getNameScope());
                        // scsInitExpr.bindExpression(this);
                        initExpr.substituteInPlace(new Expression(spC.getName()), scsInitExpr);
                    }
                }
            }
            // now create the appropriate function for the current speciesContextSpec.
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(initParm, sm.getGeometryClass()), getIdentifierSubstitutions(initExpr, initParm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
    }
    // 
    for (int i = 0; i < speciesContextSpecs.length; i++) {
        SpeciesContextSpec.SpeciesContextSpecParameter diffParm = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_DiffusionRate);
        if (diffParm != null) {
            StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(speciesContextSpecs[i].getSpeciesContext().getStructure());
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(diffParm, sm.getGeometryClass()), getIdentifierSubstitutions(diffParm.getExpression(), diffParm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
    }
    // 
    for (int i = 0; i < speciesContextSpecs.length; i++) {
        SpeciesContextSpec.SpeciesContextSpecParameter bc_xm = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueXm);
        StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(speciesContextSpecs[i].getSpeciesContext().getStructure());
        if (bc_xm != null && (bc_xm.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_xm, sm.getGeometryClass()), getIdentifierSubstitutions(bc_xm.getExpression(), bc_xm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter bc_xp = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueXp);
        if (bc_xp != null && (bc_xp.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_xp, sm.getGeometryClass()), getIdentifierSubstitutions(bc_xp.getExpression(), bc_xp.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter bc_ym = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueYm);
        if (bc_ym != null && (bc_ym.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_ym, sm.getGeometryClass()), getIdentifierSubstitutions(bc_ym.getExpression(), bc_ym.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter bc_yp = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueYp);
        if (bc_yp != null && (bc_yp.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_yp, sm.getGeometryClass()), getIdentifierSubstitutions(bc_yp.getExpression(), bc_yp.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter bc_zm = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueZm);
        if (bc_zm != null && (bc_zm.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_zm, sm.getGeometryClass()), getIdentifierSubstitutions(bc_zm.getExpression(), bc_zm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter bc_zp = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_BoundaryValueZp);
        if (bc_zp != null && (bc_zp.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(bc_zp, sm.getGeometryClass()), getIdentifierSubstitutions(bc_zp.getExpression(), bc_zp.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
        }
    }
    // 
    for (int i = 0; i < speciesContextSpecs.length; i++) {
        SpeciesContextSpec.SpeciesContextSpecParameter advection_velX = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_VelocityX);
        StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(speciesContextSpecs[i].getSpeciesContext().getStructure());
        GeometryClass geometryClass = sm.getGeometryClass();
        if (advection_velX != null && (advection_velX.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(advection_velX, geometryClass), getIdentifierSubstitutions(advection_velX.getExpression(), advection_velX.getUnitDefinition(), geometryClass), geometryClass));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter advection_velY = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_VelocityY);
        if (advection_velY != null && (advection_velY.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(advection_velY, geometryClass), getIdentifierSubstitutions(advection_velY.getExpression(), advection_velY.getUnitDefinition(), geometryClass), geometryClass));
        }
        SpeciesContextSpec.SpeciesContextSpecParameter advection_velZ = speciesContextSpecs[i].getParameterFromRole(SpeciesContextSpec.ROLE_VelocityZ);
        if (advection_velZ != null && (advection_velZ.getExpression() != null)) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(advection_velZ, geometryClass), getIdentifierSubstitutions(advection_velZ.getExpression(), advection_velZ.getUnitDefinition(), geometryClass), geometryClass));
        }
    }
    // 
    // constant species (either function or constant)
    // 
    enum1 = getSpeciesContextMappings();
    while (enum1.hasMoreElements()) {
        SpeciesContextMapping scm = (SpeciesContextMapping) enum1.nextElement();
        if (scm.getVariable() instanceof Constant) {
            varHash.addVariable(scm.getVariable());
        }
    }
    // 
    // conversion factors
    // 
    varHash.addVariable(new Constant(getMathSymbol(model.getKMOLE(), null), getIdentifierSubstitutions(model.getKMOLE().getExpression(), model.getKMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getN_PMOLE(), null), getIdentifierSubstitutions(model.getN_PMOLE().getExpression(), model.getN_PMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getKMILLIVOLTS(), null), getIdentifierSubstitutions(model.getKMILLIVOLTS().getExpression(), model.getKMILLIVOLTS().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getK_GHK(), null), getIdentifierSubstitutions(model.getK_GHK().getExpression(), model.getK_GHK().getUnitDefinition(), null)));
    // 
    for (int i = 0; i < structureMappings.length; i++) {
        StructureMapping sm = structureMappings[i];
        if (getSimulationContext().getGeometry().getDimension() == 0) {
            StructureMappingParameter sizeParm = sm.getSizeParameter();
            if (sizeParm != null && sizeParm.getExpression() != null) {
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(sizeParm, sm.getGeometryClass()), getIdentifierSubstitutions(sizeParm.getExpression(), sizeParm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
            } else {
                if (sm instanceof MembraneMapping) {
                    MembraneMapping mm = (MembraneMapping) sm;
                    StructureMappingParameter volFrac = mm.getVolumeFractionParameter();
                    if (volFrac != null && volFrac.getExpression() != null) {
                        varHash.addVariable(newFunctionOrConstant(getMathSymbol(volFrac, sm.getGeometryClass()), getIdentifierSubstitutions(volFrac.getExpression(), volFrac.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
                    }
                    StructureMappingParameter surfToVol = mm.getSurfaceToVolumeParameter();
                    if (surfToVol != null && surfToVol.getExpression() != null) {
                        varHash.addVariable(newFunctionOrConstant(getMathSymbol(surfToVol, sm.getGeometryClass()), getIdentifierSubstitutions(surfToVol.getExpression(), surfToVol.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
                    }
                }
            }
        } else {
            Parameter parm = sm.getParameterFromRole(StructureMapping.ROLE_AreaPerUnitArea);
            if (parm != null && parm.getExpression() != null && sm.getGeometryClass() instanceof SurfaceClass) {
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(parm, sm.getGeometryClass()), getIdentifierSubstitutions(parm.getExpression(), parm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
            }
            parm = sm.getParameterFromRole(StructureMapping.ROLE_AreaPerUnitVolume);
            if (parm != null && parm.getExpression() != null && sm.getGeometryClass() instanceof SubVolume) {
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(parm, sm.getGeometryClass()), getIdentifierSubstitutions(parm.getExpression(), parm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
            }
            parm = sm.getParameterFromRole(StructureMapping.ROLE_VolumePerUnitArea);
            if (parm != null && parm.getExpression() != null && sm.getGeometryClass() instanceof SurfaceClass) {
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(parm, sm.getGeometryClass()), getIdentifierSubstitutions(parm.getExpression(), parm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
            }
            parm = sm.getParameterFromRole(StructureMapping.ROLE_VolumePerUnitVolume);
            if (parm != null && parm.getExpression() != null && sm.getGeometryClass() instanceof SubVolume) {
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(parm, sm.getGeometryClass()), getIdentifierSubstitutions(parm.getExpression(), parm.getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass()));
            }
        }
    }
    // 
    // functions
    // 
    enum1 = getSpeciesContextMappings();
    while (enum1.hasMoreElements()) {
        SpeciesContextMapping scm = (SpeciesContextMapping) enum1.nextElement();
        if (scm.getVariable() == null && scm.getDependencyExpression() != null) {
            StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(scm.getSpeciesContext().getStructure());
            Variable dependentVariable = newFunctionOrConstant(getMathSymbol(scm.getSpeciesContext(), sm.getGeometryClass()), getIdentifierSubstitutions(scm.getDependencyExpression(), scm.getSpeciesContext().getUnitDefinition(), sm.getGeometryClass()), sm.getGeometryClass());
            dependentVariable.setDomain(new Domain(sm.getGeometryClass()));
            varHash.addVariable(dependentVariable);
        }
    }
    // 
    for (int i = 0; i < fieldMathMappingParameters.length; i++) {
        if (fieldMathMappingParameters[i] instanceof UnitFactorParameter) {
            GeometryClass geometryClass = fieldMathMappingParameters[i].getGeometryClass();
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(fieldMathMappingParameters[i], geometryClass), getIdentifierSubstitutions(fieldMathMappingParameters[i].getExpression(), fieldMathMappingParameters[i].getUnitDefinition(), geometryClass), fieldMathMappingParameters[i].getGeometryClass()));
        }
    }
    // 
    // set Variables to MathDescription all at once with the order resolved by "VariableHash"
    // 
    mathDesc.setAllVariables(varHash.getAlphabeticallyOrderedVariables());
    // 
    if (getSimulationContext().getGeometryContext().getGeometry() != null) {
        try {
            mathDesc.setGeometry(getSimulationContext().getGeometryContext().getGeometry());
        } catch (java.beans.PropertyVetoException e) {
            e.printStackTrace(System.out);
            throw new MappingException("failure setting geometry " + e.getMessage());
        }
    } else {
        throw new MappingException("geometry must be defined");
    }
    // 
    // create subdomains (volume and surfaces)
    // 
    GeometryClass[] geometryClasses = getSimulationContext().getGeometryContext().getGeometry().getGeometryClasses();
    for (int k = 0; k < geometryClasses.length; k++) {
        if (geometryClasses[k] instanceof SubVolume) {
            SubVolume subVolume = (SubVolume) geometryClasses[k];
            // 
            // get priority of subDomain
            // 
            // now does not have to match spatial feature, *BUT* needs to be unique
            int priority = k;
            // 
            // create subDomain
            // 
            CompartmentSubDomain subDomain = new CompartmentSubDomain(subVolume.getName(), priority);
            mathDesc.addSubDomain(subDomain);
            // 
            // assign boundary condition types
            // 
            StructureMapping[] mappedSMs = getSimulationContext().getGeometryContext().getStructureMappings(subVolume);
            FeatureMapping mappedFM = null;
            for (int i = 0; i < mappedSMs.length; i++) {
                if (mappedSMs[i] instanceof FeatureMapping) {
                    if (mappedFM != null) {
                        lg.warn("WARNING:::: MathMapping.refreshMathDescription() ... assigning boundary condition types not unique");
                    }
                    mappedFM = (FeatureMapping) mappedSMs[i];
                }
            }
            if (mappedFM != null) {
                subDomain.setBoundaryConditionXm(mappedFM.getBoundaryConditionTypeXm());
                subDomain.setBoundaryConditionXp(mappedFM.getBoundaryConditionTypeXp());
                if (getSimulationContext().getGeometry().getDimension() > 1) {
                    subDomain.setBoundaryConditionYm(mappedFM.getBoundaryConditionTypeYm());
                    subDomain.setBoundaryConditionYp(mappedFM.getBoundaryConditionTypeYp());
                }
                if (getSimulationContext().getGeometry().getDimension() > 2) {
                    subDomain.setBoundaryConditionZm(mappedFM.getBoundaryConditionTypeZm());
                    subDomain.setBoundaryConditionZp(mappedFM.getBoundaryConditionTypeZp());
                }
            }
        } else if (geometryClasses[k] instanceof SurfaceClass) {
            SurfaceClass surfaceClass = (SurfaceClass) geometryClasses[k];
            // determine membrane inside and outside subvolume
            // this preserves backward compatibility so that membrane subdomain
            // inside and outside correspond to structure hierarchy when present
            Pair<SubVolume, SubVolume> ret = DiffEquMathMapping.computeBoundaryConditionSource(model, simContext, surfaceClass);
            SubVolume innerSubVolume = ret.one;
            SubVolume outerSubVolume = ret.two;
            // 
            // create subDomain
            // 
            CompartmentSubDomain outerCompartment = mathDesc.getCompartmentSubDomain(outerSubVolume.getName());
            CompartmentSubDomain innerCompartment = mathDesc.getCompartmentSubDomain(innerSubVolume.getName());
            MembraneSubDomain memSubDomain = new MembraneSubDomain(innerCompartment, outerCompartment, surfaceClass.getName());
            mathDesc.addSubDomain(memSubDomain);
        }
    }
    // 
    // create Particle Contexts for all Particle Variables
    // 
    Enumeration<SpeciesContextMapping> enumSCM = getSpeciesContextMappings();
    Expression unitFactor = getUnitFactor(modelUnitSystem.getStochasticSubstanceUnit().divideBy(modelUnitSystem.getVolumeSubstanceUnit()));
    while (enumSCM.hasMoreElements()) {
        SpeciesContextMapping scm = enumSCM.nextElement();
        SpeciesContext sc = scm.getSpeciesContext();
        StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(sc.getStructure());
        SpeciesContextSpec scs = getSimulationContext().getReactionContext().getSpeciesContextSpec(sc);
        if (scm.getVariable() instanceof ParticleVariable && scm.getDependencyExpression() == null) {
            ParticleVariable particleVariable = (ParticleVariable) scm.getVariable();
            // 
            // initial distribution of particles
            // 
            ArrayList<ParticleInitialCondition> particleInitialConditions = new ArrayList<ParticleInitialCondition>();
            ParticleInitialCondition pic = null;
            if (getSimulationContext().isUsingConcentration()) {
                Expression initialDistribution = scs.getInitialConcentrationParameter().getExpression() == null ? null : new Expression(getMathSymbol(scs.getInitialConcentrationParameter(), sm.getGeometryClass()));
                if (particleVariable instanceof VolumeParticleVariable) {
                    initialDistribution = Expression.mult(initialDistribution, unitFactor);
                }
                pic = new ParticleInitialConditionConcentration(initialDistribution);
            } else {
                Expression initialCount = scs.getInitialCountParameter().getExpression() == null ? null : new Expression(getMathSymbol(scs.getInitialCountParameter(), sm.getGeometryClass()));
                if (initialCount == null) {
                    throw new MappingException("initialCount not defined for speciesContext " + scs.getSpeciesContext().getName());
                }
                Expression locationX = new Expression("u");
                Expression locationY = new Expression("u");
                Expression locationZ = new Expression("u");
                pic = new ParticleInitialConditionCount(initialCount, locationX, locationY, locationZ);
            }
            particleInitialConditions.add(pic);
            // 
            // diffusion
            // 
            Expression diffusion = new Expression(getMathSymbol(scs.getDiffusionParameter(), sm.getGeometryClass()));
            Expression driftXExp = null;
            if (scs.getVelocityXParameter().getExpression() != null) {
                driftXExp = new Expression(getMathSymbol(scs.getVelocityXParameter(), sm.getGeometryClass()));
            } else {
                SpatialQuantity[] velX_quantities = scs.getVelocityQuantities(QuantityComponent.X);
                if (velX_quantities.length > 0) {
                    int numRegions = simContext.getGeometry().getGeometrySurfaceDescription().getGeometricRegions(sm.getGeometryClass()).length;
                    if (velX_quantities.length == 1 && numRegions == 1) {
                        driftXExp = new Expression(getMathSymbol(velX_quantities[0], sm.getGeometryClass()));
                    } else {
                        throw new MappingException("multiple advection velocities enabled set for multiple volume domains ");
                    }
                }
            }
            Expression driftYExp = null;
            if (scs.getVelocityYParameter().getExpression() != null) {
                driftYExp = new Expression(getMathSymbol(scs.getVelocityYParameter(), sm.getGeometryClass()));
            } else {
                SpatialQuantity[] velY_quantities = scs.getVelocityQuantities(QuantityComponent.Y);
                if (velY_quantities.length > 0) {
                    int numRegions = simContext.getGeometry().getGeometrySurfaceDescription().getGeometricRegions(sm.getGeometryClass()).length;
                    if (velY_quantities.length == 1 && numRegions == 1) {
                        driftYExp = new Expression(getMathSymbol(velY_quantities[0], sm.getGeometryClass()));
                    } else {
                        throw new MappingException("multiple advection velocities enabled set for multiple volume domains ");
                    }
                }
            }
            Expression driftZExp = null;
            if (scs.getVelocityZParameter().getExpression() != null) {
                driftZExp = new Expression(getMathSymbol(scs.getVelocityZParameter(), sm.getGeometryClass()));
            } else {
                SpatialQuantity[] velZ_quantities = scs.getVelocityQuantities(QuantityComponent.Z);
                if (velZ_quantities.length > 0) {
                    int numRegions = simContext.getGeometry().getGeometrySurfaceDescription().getGeometricRegions(sm.getGeometryClass()).length;
                    if (velZ_quantities.length == 1 && numRegions == 1) {
                        driftZExp = new Expression(getMathSymbol(velZ_quantities[0], sm.getGeometryClass()));
                    } else {
                        throw new MappingException("multiple advection velocities enabled set for multiple volume domains ");
                    }
                }
            }
            ParticleProperties particleProperties = new ParticleProperties(particleVariable, diffusion, driftXExp, driftYExp, driftZExp, particleInitialConditions);
            GeometryClass myGC = sm.getGeometryClass();
            if (myGC == null) {
                throw new MappingException("Application '" + getSimulationContext().getName() + "'\nGeometry->StructureMapping->(" + sm.getStructure().getTypeName() + ")'" + sm.getStructure().getName() + "' must be mapped to geometry domain.\n(see 'Problems' tab)");
            }
            SubDomain subDomain = mathDesc.getSubDomain(myGC.getName());
            subDomain.addParticleProperties(particleProperties);
        }
    }
    for (ReactionStep reactionStep : reactionSteps) {
        Kinetics kinetics = reactionStep.getKinetics();
        StructureMapping sm = getSimulationContext().getGeometryContext().getStructureMapping(reactionStep.getStructure());
        GeometryClass reactionStepGeometryClass = sm.getGeometryClass();
        SubDomain subdomain = mathDesc.getSubDomain(reactionStepGeometryClass.getName());
        KineticsParameter reactionRateParameter = null;
        if (kinetics instanceof LumpedKinetics) {
            reactionRateParameter = ((LumpedKinetics) kinetics).getLumpedReactionRateParameter();
        } else {
            reactionRateParameter = ((DistributedKinetics) kinetics).getReactionRateParameter();
        }
        // macroscopic_irreversible/Microscopic_irreversible for bimolecular membrane reactions. They will NOT go through MassAction solver.
        if (kinetics.getKineticsDescription().equals(KineticsDescription.Macroscopic_irreversible) || kinetics.getKineticsDescription().equals(KineticsDescription.Microscopic_irreversible)) {
            Expression radiusExp = getIdentifierSubstitutions(reactionStep.getKinetics().getKineticsParameterFromRole(Kinetics.ROLE_Binding_Radius).getExpression(), modelUnitSystem.getBindingRadiusUnit(), reactionStepGeometryClass);
            if (radiusExp != null) {
                Expression expCopy = new Expression(radiusExp);
                try {
                    MassActionSolver.substituteParameters(expCopy, true).evaluateConstant();
                } catch (ExpressionException e) {
                    throw new MathException(VCellErrorMessages.getMassActionSolverMessage(reactionStep.getName(), "Problem in binding radius of " + reactionStep.getName() + ":  '" + radiusExp.infix() + "', " + e.getMessage()));
                }
            } else {
                throw new MathException(VCellErrorMessages.getMassActionSolverMessage(reactionStep.getName(), "Binding radius of " + reactionStep.getName() + " is null."));
            }
            List<ParticleVariable> reactantParticles = new ArrayList<ParticleVariable>();
            List<ParticleVariable> productParticles = new ArrayList<ParticleVariable>();
            List<Action> forwardActions = new ArrayList<Action>();
            for (ReactionParticipant rp : reactionStep.getReactionParticipants()) {
                SpeciesContext sc = rp.getSpeciesContext();
                SpeciesContextSpec scs = getSimulationContext().getReactionContext().getSpeciesContextSpec(sc);
                GeometryClass scGeometryClass = getSimulationContext().getGeometryContext().getStructureMapping(sc.getStructure()).getGeometryClass();
                String varName = getMathSymbol(sc, scGeometryClass);
                Variable var = mathDesc.getVariable(varName);
                if (var instanceof ParticleVariable) {
                    ParticleVariable particle = (ParticleVariable) var;
                    if (rp instanceof Reactant) {
                        reactantParticles.add(particle);
                        if (!scs.isConstant() && !scs.isForceContinuous()) {
                            for (int i = 0; i < Math.abs(rp.getStoichiometry()); i++) {
                                if (radiusExp != null) {
                                    forwardActions.add(Action.createDestroyAction(particle));
                                }
                            }
                        }
                    } else if (rp instanceof Product) {
                        productParticles.add(particle);
                        if (!scs.isConstant() && !scs.isForceContinuous()) {
                            for (int i = 0; i < Math.abs(rp.getStoichiometry()); i++) {
                                if (radiusExp != null) {
                                    forwardActions.add(Action.createCreateAction(particle));
                                }
                            }
                        }
                    }
                } else {
                    throw new MappingException("particle variable '" + varName + "' not found");
                }
            }
            JumpProcessRateDefinition bindingRadius = new InteractionRadius(radiusExp);
            // get jump process name
            String jpName = TokenMangler.mangleToSName(reactionStep.getName());
            // only for NFSim/Rules for now.
            ProcessSymmetryFactor processSymmetryFactor = null;
            if (forwardActions.size() > 0) {
                ParticleJumpProcess forwardProcess = new ParticleJumpProcess(jpName, reactantParticles, bindingRadius, forwardActions, processSymmetryFactor);
                subdomain.addParticleJumpProcess(forwardProcess);
            }
        } else // other type of reactions
        {
            /* check the reaction rate law to see if we need to decompose a reaction(reversible) into two jump processes.
			   rate constants are important in calculating the probability rate.
			   for Mass Action, we use KForward and KReverse, 
			   for General Kinetics we parse reaction rate J to see if it is in Mass Action form.
			 */
            Expression forwardRate = null;
            Expression reverseRate = null;
            // Using the MassActionFunction to write out the math description
            MassActionSolver.MassActionFunction maFunc = null;
            if (kinetics.getKineticsDescription().equals(KineticsDescription.MassAction) || kinetics.getKineticsDescription().equals(KineticsDescription.General) || kinetics.getKineticsDescription().equals(KineticsDescription.GeneralPermeability)) {
                Expression rateExp = kinetics.getKineticsParameterFromRole(Kinetics.ROLE_ReactionRate).getExpression();
                Parameter forwardRateParameter = null;
                Parameter reverseRateParameter = null;
                if (kinetics.getKineticsDescription().equals(KineticsDescription.MassAction)) {
                    forwardRateParameter = kinetics.getKineticsParameterFromRole(Kinetics.ROLE_KForward);
                    reverseRateParameter = kinetics.getKineticsParameterFromRole(Kinetics.ROLE_KReverse);
                } else if (kinetics.getKineticsDescription().equals(KineticsDescription.GeneralPermeability)) {
                    forwardRateParameter = kinetics.getKineticsParameterFromRole(Kinetics.ROLE_Permeability);
                    reverseRateParameter = kinetics.getKineticsParameterFromRole(Kinetics.ROLE_Permeability);
                }
                maFunc = MassActionSolver.solveMassAction(forwardRateParameter, reverseRateParameter, rateExp, reactionStep);
                if (maFunc.getForwardRate() == null && maFunc.getReverseRate() == null) {
                    throw new MappingException("Cannot generate stochastic math mapping for the reaction:" + reactionStep.getName() + "\nLooking for the rate function according to the form of k1*Reactant1^Stoir1*Reactant2^Stoir2...-k2*Product1^Stoip1*Product2^Stoip2.");
                } else {
                    if (maFunc.getForwardRate() != null) {
                        forwardRate = maFunc.getForwardRate();
                    }
                    if (maFunc.getReverseRate() != null) {
                        reverseRate = maFunc.getReverseRate();
                    }
                }
            }
            if (maFunc != null) {
                // if the reaction has forward rate (Mass action,HMMs), or don't have either forward or reverse rate (some other rate laws--like general)
                // we process it as forward reaction
                List<ParticleVariable> reactantParticles = new ArrayList<ParticleVariable>();
                List<ParticleVariable> productParticles = new ArrayList<ParticleVariable>();
                List<Action> forwardActions = new ArrayList<Action>();
                List<Action> reverseActions = new ArrayList<Action>();
                List<ReactionParticipant> reactants = maFunc.getReactants();
                List<ReactionParticipant> products = maFunc.getProducts();
                for (ReactionParticipant rp : reactants) {
                    SpeciesContext sc = rp.getSpeciesContext();
                    SpeciesContextSpec scs = getSimulationContext().getReactionContext().getSpeciesContextSpec(sc);
                    GeometryClass scGeometryClass = getSimulationContext().getGeometryContext().getStructureMapping(sc.getStructure()).getGeometryClass();
                    String varName = getMathSymbol(sc, scGeometryClass);
                    Variable var = mathDesc.getVariable(varName);
                    if (var instanceof ParticleVariable) {
                        ParticleVariable particle = (ParticleVariable) var;
                        reactantParticles.add(particle);
                        if (!scs.isConstant() && !scs.isForceContinuous()) {
                            for (int i = 0; i < Math.abs(rp.getStoichiometry()); i++) {
                                if (forwardRate != null) {
                                    forwardActions.add(Action.createDestroyAction(particle));
                                }
                                if (reverseRate != null) {
                                    reverseActions.add(Action.createCreateAction(particle));
                                }
                            }
                        }
                    } else {
                        throw new MappingException("particle variable '" + varName + "' not found");
                    }
                }
                for (ReactionParticipant rp : products) {
                    SpeciesContext sc = rp.getSpeciesContext();
                    SpeciesContextSpec scs = getSimulationContext().getReactionContext().getSpeciesContextSpec(sc);
                    GeometryClass scGeometryClass = getSimulationContext().getGeometryContext().getStructureMapping(sc.getStructure()).getGeometryClass();
                    String varName = getMathSymbol(sc, scGeometryClass);
                    Variable var = mathDesc.getVariable(varName);
                    if (var instanceof ParticleVariable) {
                        ParticleVariable particle = (ParticleVariable) var;
                        productParticles.add(particle);
                        if (!scs.isConstant() && !scs.isForceContinuous()) {
                            for (int i = 0; i < Math.abs(rp.getStoichiometry()); i++) {
                                if (forwardRate != null) {
                                    forwardActions.add(Action.createCreateAction(particle));
                                }
                                if (reverseRate != null) {
                                    reverseActions.add(Action.createDestroyAction(particle));
                                }
                            }
                        }
                    } else {
                        throw new MappingException("particle variable '" + varName + "' not found");
                    }
                }
                // 
                // There are two unit conversions required:
                // 
                // 1) convert entire reaction rate from vcell reaction units to Smoldyn units (molecules/lengthunit^dim/timeunit)
                // (where dim is 2 for membrane reactions and 3 for volume reactions)
                // 
                // for forward rates:
                // 2) convert each reactant from Smoldyn units (molecules/lengthunit^dim) to VCell units
                // (where dim is 2 for membrane reactants and 3 for volume reactants)
                // 
                // or
                // 
                // for reverse rates:
                // 2) convert each product from Smoldyn units (molecules/lengthunit^dim) to VCell units
                // (where dim is 2 for membrane products and 3 for volume products)
                // 
                RationalNumber reactionLocationDim = new RationalNumber(reactionStep.getStructure().getDimension());
                VCUnitDefinition timeUnit = modelUnitSystem.getTimeUnit();
                VCUnitDefinition smoldynReactionSizeUnit = modelUnitSystem.getLengthUnit().raiseTo(reactionLocationDim);
                VCUnitDefinition smoldynSubstanceUnit = modelUnitSystem.getStochasticSubstanceUnit();
                VCUnitDefinition smoldynReactionRateUnit = smoldynSubstanceUnit.divideBy(smoldynReactionSizeUnit).divideBy(timeUnit);
                VCUnitDefinition vcellReactionRateUnit = reactionRateParameter.getUnitDefinition();
                VCUnitDefinition reactionUnitFactor = smoldynReactionRateUnit.divideBy(vcellReactionRateUnit);
                if (forwardRate != null) {
                    VCUnitDefinition smoldynReactantsUnit = modelUnitSystem.getInstance_DIMENSIONLESS();
                    // start with factor to translate entire reaction rate.
                    VCUnitDefinition forwardUnitFactor = reactionUnitFactor;
                    // 
                    for (ReactionParticipant reactant : maFunc.getReactants()) {
                        VCUnitDefinition vcellReactantUnit = reactant.getSpeciesContext().getUnitDefinition();
                        boolean bForceContinuous = simContext.getReactionContext().getSpeciesContextSpec(reactant.getSpeciesContext()).isForceContinuous();
                        VCUnitDefinition smoldynReactantUnit = null;
                        if (bForceContinuous) {
                            // reactant is continuous (vcell units)
                            smoldynReactantUnit = reactant.getSpeciesContext().getUnitDefinition();
                        } else {
                            // reactant is a particle (smoldyn units)
                            RationalNumber reactantLocationDim = new RationalNumber(reactant.getStructure().getDimension());
                            VCUnitDefinition smoldynReactantSize = modelUnitSystem.getLengthUnit().raiseTo(reactantLocationDim);
                            smoldynReactantUnit = smoldynSubstanceUnit.divideBy(smoldynReactantSize);
                        }
                        // keep track of units of all reactants
                        smoldynReactantsUnit = smoldynReactantsUnit.multiplyBy(smoldynReactantUnit);
                        RationalNumber reactantStoichiometry = new RationalNumber(reactant.getStoichiometry());
                        VCUnitDefinition reactantUnitFactor = (vcellReactantUnit.divideBy(smoldynReactantUnit)).raiseTo(reactantStoichiometry);
                        // accumulate unit factors for all reactants
                        forwardUnitFactor = forwardUnitFactor.multiplyBy(reactantUnitFactor);
                    }
                    forwardRate = Expression.mult(forwardRate, getUnitFactor(forwardUnitFactor));
                    VCUnitDefinition smoldynExpectedForwardRateUnit = smoldynReactionRateUnit.divideBy(smoldynReactantsUnit);
                    // get probability
                    Expression exp = getIdentifierSubstitutions(forwardRate, smoldynExpectedForwardRateUnit, reactionStepGeometryClass).flatten();
                    JumpProcessRateDefinition partRateDef = new MacroscopicRateConstant(exp);
                    // create particle jump process
                    String jpName = TokenMangler.mangleToSName(reactionStep.getName());
                    // only for NFSim/Rules for now.
                    ProcessSymmetryFactor processSymmetryFactor = null;
                    if (forwardActions.size() > 0) {
                        ParticleJumpProcess forwardProcess = new ParticleJumpProcess(jpName, reactantParticles, partRateDef, forwardActions, processSymmetryFactor);
                        subdomain.addParticleJumpProcess(forwardProcess);
                    }
                }
                // end of forward rate not null
                if (reverseRate != null) {
                    VCUnitDefinition smoldynProductsUnit = modelUnitSystem.getInstance_DIMENSIONLESS();
                    // start with factor to translate entire reaction rate.
                    VCUnitDefinition reverseUnitFactor = reactionUnitFactor;
                    // 
                    for (ReactionParticipant product : maFunc.getProducts()) {
                        VCUnitDefinition vcellProductUnit = product.getSpeciesContext().getUnitDefinition();
                        boolean bForceContinuous = simContext.getReactionContext().getSpeciesContextSpec(product.getSpeciesContext()).isForceContinuous();
                        VCUnitDefinition smoldynProductUnit = null;
                        if (bForceContinuous) {
                            smoldynProductUnit = product.getSpeciesContext().getUnitDefinition();
                        } else {
                            RationalNumber productLocationDim = new RationalNumber(product.getStructure().getDimension());
                            VCUnitDefinition smoldynProductSize = modelUnitSystem.getLengthUnit().raiseTo(productLocationDim);
                            smoldynProductUnit = smoldynSubstanceUnit.divideBy(smoldynProductSize);
                        }
                        // keep track of units of all products
                        smoldynProductsUnit = smoldynProductsUnit.multiplyBy(smoldynProductUnit);
                        RationalNumber productStoichiometry = new RationalNumber(product.getStoichiometry());
                        VCUnitDefinition productUnitFactor = (vcellProductUnit.divideBy(smoldynProductUnit)).raiseTo(productStoichiometry);
                        // accumulate unit factors for all products
                        reverseUnitFactor = reverseUnitFactor.multiplyBy(productUnitFactor);
                    }
                    reverseRate = Expression.mult(reverseRate, getUnitFactor(reverseUnitFactor));
                    VCUnitDefinition smoldynExpectedReverseRateUnit = smoldynReactionRateUnit.divideBy(smoldynProductsUnit);
                    // get probability
                    Expression exp = getIdentifierSubstitutions(reverseRate, smoldynExpectedReverseRateUnit, reactionStepGeometryClass).flatten();
                    JumpProcessRateDefinition partProbRate = new MacroscopicRateConstant(exp);
                    // get jump process name
                    String jpName = TokenMangler.mangleToSName(reactionStep.getName() + "_reverse");
                    // only for NFSim/Rules for now.
                    ProcessSymmetryFactor processSymmetryFactor = null;
                    if (reverseActions.size() > 0) {
                        ParticleJumpProcess reverseProcess = new ParticleJumpProcess(jpName, productParticles, partProbRate, reverseActions, processSymmetryFactor);
                        subdomain.addParticleJumpProcess(reverseProcess);
                    }
                }
            // end of reverse rate not null
            }
        // end of maFunc not null
        }
    // end of reaction step for loop
    }
    // 
    for (int i = 0; i < fieldMathMappingParameters.length; i++) {
        if (fieldMathMappingParameters[i] instanceof UnitFactorParameter) {
            GeometryClass geometryClass = fieldMathMappingParameters[i].getGeometryClass();
            Variable variable = newFunctionOrConstant(getMathSymbol(fieldMathMappingParameters[i], geometryClass), getIdentifierSubstitutions(fieldMathMappingParameters[i].getExpression(), fieldMathMappingParameters[i].getUnitDefinition(), geometryClass), fieldMathMappingParameters[i].getGeometryClass());
            if (mathDesc.getVariable(variable.getName()) == null) {
                mathDesc.addVariable(variable);
            }
        }
    }
    if (!mathDesc.isValid()) {
        lg.warn(mathDesc.getVCML_database());
        throw new MappingException("generated an invalid mathDescription: " + mathDesc.getWarning());
    }
    if (lg.isDebugEnabled()) {
        System.out.println("]]]]]]]]]]]]]]]]]]]]]] VCML string begin ]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]");
        System.out.println(mathDesc.getVCML());
        System.out.println("]]]]]]]]]]]]]]]]]]]]]] VCML string end ]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]]");
    }
}
Also used : MembraneSubDomain(cbit.vcell.math.MembraneSubDomain) LumpedKinetics(cbit.vcell.model.LumpedKinetics) MathDescription(cbit.vcell.math.MathDescription) ArrayList(java.util.ArrayList) Product(cbit.vcell.model.Product) SpeciesContext(cbit.vcell.model.SpeciesContext) StructureMappingParameter(cbit.vcell.mapping.StructureMapping.StructureMappingParameter) Reactant(cbit.vcell.model.Reactant) ExpressionException(cbit.vcell.parser.ExpressionException) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) SubDomain(cbit.vcell.math.SubDomain) MembraneSubDomain(cbit.vcell.math.MembraneSubDomain) KineticsParameter(cbit.vcell.model.Kinetics.KineticsParameter) SubVolume(cbit.vcell.geometry.SubVolume) Vector(java.util.Vector) SpatialQuantity(cbit.vcell.mapping.spatial.SpatialObject.SpatialQuantity) SpeciesContextSpecParameter(cbit.vcell.mapping.SpeciesContextSpec.SpeciesContextSpecParameter) SpeciesContextSpecParameter(cbit.vcell.mapping.SpeciesContextSpec.SpeciesContextSpecParameter) JumpProcessRateDefinition(cbit.vcell.math.JumpProcessRateDefinition) InteractionRadius(cbit.vcell.math.InteractionRadius) ParticleJumpProcess(cbit.vcell.math.ParticleJumpProcess) ModelParameter(cbit.vcell.model.Model.ModelParameter) VCUnitDefinition(cbit.vcell.units.VCUnitDefinition) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) ParticleInitialCondition(cbit.vcell.math.ParticleProperties.ParticleInitialCondition) ReactionStep(cbit.vcell.model.ReactionStep) ParticleProperties(cbit.vcell.math.ParticleProperties) Kinetics(cbit.vcell.model.Kinetics) DistributedKinetics(cbit.vcell.model.DistributedKinetics) LumpedKinetics(cbit.vcell.model.LumpedKinetics) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) SubDomain(cbit.vcell.math.SubDomain) Domain(cbit.vcell.math.Variable.Domain) MembraneSubDomain(cbit.vcell.math.MembraneSubDomain) ReactionParticipant(cbit.vcell.model.ReactionParticipant) GeometryClass(cbit.vcell.geometry.GeometryClass) Action(cbit.vcell.math.Action) VolumeParticleVariable(cbit.vcell.math.VolumeParticleVariable) MembraneParticleVariable(cbit.vcell.math.MembraneParticleVariable) ParticleVariable(cbit.vcell.math.ParticleVariable) Variable(cbit.vcell.math.Variable) SpeciesContextSpecProxyParameter(cbit.vcell.mapping.SpeciesContextSpec.SpeciesContextSpecProxyParameter) SurfaceClass(cbit.vcell.geometry.SurfaceClass) VariableHash(cbit.vcell.math.VariableHash) VolumeParticleVariable(cbit.vcell.math.VolumeParticleVariable) MembraneParticleVariable(cbit.vcell.math.MembraneParticleVariable) ParticleVariable(cbit.vcell.math.ParticleVariable) MacroscopicRateConstant(cbit.vcell.math.MacroscopicRateConstant) Constant(cbit.vcell.math.Constant) SymbolTableEntry(cbit.vcell.parser.SymbolTableEntry) MacroscopicRateConstant(cbit.vcell.math.MacroscopicRateConstant) RationalNumber(ucar.units_vcell.RationalNumber) ModelUnitSystem(cbit.vcell.model.ModelUnitSystem) Pair(org.vcell.util.Pair) ParticleInitialConditionConcentration(cbit.vcell.math.ParticleProperties.ParticleInitialConditionConcentration) ProcessSymmetryFactor(cbit.vcell.math.ParticleJumpProcess.ProcessSymmetryFactor) Expression(cbit.vcell.parser.Expression) VolumeParticleVariable(cbit.vcell.math.VolumeParticleVariable) MathException(cbit.vcell.math.MathException) Model(cbit.vcell.model.Model) StructureMappingParameter(cbit.vcell.mapping.StructureMapping.StructureMappingParameter) Parameter(cbit.vcell.model.Parameter) KineticsParameter(cbit.vcell.model.Kinetics.KineticsParameter) SpeciesContextSpecProxyParameter(cbit.vcell.mapping.SpeciesContextSpec.SpeciesContextSpecProxyParameter) ModelParameter(cbit.vcell.model.Model.ModelParameter) SpeciesContextSpecParameter(cbit.vcell.mapping.SpeciesContextSpec.SpeciesContextSpecParameter) MassActionSolver(cbit.vcell.model.MassActionSolver) ParticleInitialConditionCount(cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)

Example 5 with ParticleInitialConditionCount

use of cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount in project vcell by virtualcell.

the class RulebasedMathMapping method refreshMathDescription.

/**
 * This method was created in VisualAge.
 */
@Override
protected void refreshMathDescription() throws MappingException, MatrixException, MathException, ExpressionException, ModelException {
    // use local variable instead of using getter all the time.
    SimulationContext simContext = getSimulationContext();
    GeometryClass geometryClass = simContext.getGeometry().getGeometrySpec().getSubVolumes()[0];
    Domain domain = new Domain(geometryClass);
    // local structure mapping list
    StructureMapping[] structureMappings = simContext.getGeometryContext().getStructureMappings();
    // We have to check if all the reactions are able to transform to stochastic jump processes before generating the math.
    String stochChkMsg = simContext.getModel().isValidForStochApp();
    if (!(stochChkMsg.equals(""))) {
        throw new ModelException("Problem updating math description: " + simContext.getName() + "\n" + stochChkMsg);
    }
    simContext.checkValidity();
    // 
    if (simContext.getGeometry().getDimension() > 0) {
        throw new MappingException("rule-based particle math mapping not implemented for spatial geometry - dimension >= 1");
    }
    // 
    for (int i = 0; i < structureMappings.length; i++) {
        if (structureMappings[i] instanceof MembraneMapping) {
            if (((MembraneMapping) structureMappings[i]).getCalculateVoltage()) {
                throw new MappingException("electric potential not yet supported for particle models");
            }
        }
    }
    // 
    // fail if any events
    // 
    BioEvent[] bioEvents = simContext.getBioEvents();
    if (bioEvents != null && bioEvents.length > 0) {
        throw new MappingException("events not yet supported for particle-based models");
    }
    // 
    // verify that all structures are mapped to subvolumes and all subvolumes are mapped to a structure
    // 
    Structure[] structures = simContext.getGeometryContext().getModel().getStructures();
    for (int i = 0; i < structures.length; i++) {
        StructureMapping sm = simContext.getGeometryContext().getStructureMapping(structures[i]);
        if (sm == null || (sm instanceof FeatureMapping && ((FeatureMapping) sm).getGeometryClass() == null)) {
            throw new MappingException("model structure '" + structures[i].getName() + "' not mapped to a geometry subVolume");
        }
        if (sm != null && (sm instanceof MembraneMapping) && ((MembraneMapping) sm).getVolumeFractionParameter() != null) {
            Expression volFractExp = ((MembraneMapping) sm).getVolumeFractionParameter().getExpression();
            try {
                if (volFractExp != null) {
                    double volFract = volFractExp.evaluateConstant();
                    if (volFract >= 1.0) {
                        throw new MappingException("model structure '" + (getSimulationContext().getModel().getStructureTopology().getInsideFeature(((MembraneMapping) sm).getMembrane()).getName() + "' has volume fraction >= 1.0"));
                    }
                }
            } catch (ExpressionException e) {
                e.printStackTrace(System.out);
            }
        }
    }
    SubVolume[] subVolumes = simContext.getGeometryContext().getGeometry().getGeometrySpec().getSubVolumes();
    for (int i = 0; i < subVolumes.length; i++) {
        Structure[] mappedStructures = simContext.getGeometryContext().getStructuresFromGeometryClass(subVolumes[i]);
        if (mappedStructures == null || mappedStructures.length == 0) {
            throw new MappingException("geometry subVolume '" + subVolumes[i].getName() + "' not mapped from a model structure");
        }
    }
    // 
    // gather only those reactionRules that are not "excluded"
    // 
    ArrayList<ReactionRule> rrList = new ArrayList<ReactionRule>();
    for (ReactionRuleSpec reactionRuleSpec : simContext.getReactionContext().getReactionRuleSpecs()) {
        if (!reactionRuleSpec.isExcluded()) {
            rrList.add(reactionRuleSpec.getReactionRule());
        }
    }
    // 
    for (ReactionRule reactionRule : rrList) {
        UnresolvedParameter[] unresolvedParameters = reactionRule.getKineticLaw().getUnresolvedParameters();
        if (unresolvedParameters != null && unresolvedParameters.length > 0) {
            StringBuffer buffer = new StringBuffer();
            for (int j = 0; j < unresolvedParameters.length; j++) {
                if (j > 0) {
                    buffer.append(", ");
                }
                buffer.append(unresolvedParameters[j].getName());
            }
            throw new MappingException("In Application '" + simContext.getName() + "', " + reactionRule.getDisplayType() + " '" + reactionRule.getName() + "' contains unresolved identifier(s): " + buffer);
        }
    }
    // 
    // create new MathDescription (based on simContext's previous MathDescription if possible)
    // 
    MathDescription oldMathDesc = simContext.getMathDescription();
    mathDesc = null;
    if (oldMathDesc != null) {
        if (oldMathDesc.getVersion() != null) {
            mathDesc = new MathDescription(oldMathDesc.getVersion());
        } else {
            mathDesc = new MathDescription(oldMathDesc.getName());
        }
    } else {
        mathDesc = new MathDescription(simContext.getName() + "_generated");
    }
    // 
    // temporarily place all variables in a hashtable (before binding) and discarding duplicates
    // 
    VariableHash varHash = new VariableHash();
    // 
    // conversion factors
    // 
    Model model = simContext.getModel();
    varHash.addVariable(new Constant(getMathSymbol(model.getKMOLE(), null), getIdentifierSubstitutions(model.getKMOLE().getExpression(), model.getKMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getN_PMOLE(), null), getIdentifierSubstitutions(model.getN_PMOLE().getExpression(), model.getN_PMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getPI_CONSTANT(), null), getIdentifierSubstitutions(model.getPI_CONSTANT().getExpression(), model.getPI_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getFARADAY_CONSTANT(), null), getIdentifierSubstitutions(model.getFARADAY_CONSTANT().getExpression(), model.getFARADAY_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getFARADAY_CONSTANT_NMOLE(), null), getIdentifierSubstitutions(model.getFARADAY_CONSTANT_NMOLE().getExpression(), model.getFARADAY_CONSTANT_NMOLE().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getGAS_CONSTANT(), null), getIdentifierSubstitutions(model.getGAS_CONSTANT().getExpression(), model.getGAS_CONSTANT().getUnitDefinition(), null)));
    varHash.addVariable(new Constant(getMathSymbol(model.getTEMPERATURE(), null), getIdentifierSubstitutions(new Expression(simContext.getTemperatureKelvin()), model.getTEMPERATURE().getUnitDefinition(), null)));
    Enumeration<SpeciesContextMapping> enum1 = getSpeciesContextMappings();
    while (enum1.hasMoreElements()) {
        SpeciesContextMapping scm = enum1.nextElement();
        if (scm.getVariable() instanceof StochVolVariable) {
            varHash.addVariable(scm.getVariable());
        }
    }
    // deals with model parameters
    ModelParameter[] modelParameters = simContext.getModel().getModelParameters();
    for (int j = 0; j < modelParameters.length; j++) {
        Expression expr = getSubstitutedExpr(modelParameters[j].getExpression(), true, false);
        expr = getIdentifierSubstitutions(expr, modelParameters[j].getUnitDefinition(), geometryClass);
        varHash.addVariable(newFunctionOrConstant(getMathSymbol(modelParameters[j], geometryClass), expr, geometryClass));
    }
    // added July 2009, ElectricalStimulusParameter electric mapping tab
    ElectricalStimulus[] elecStimulus = simContext.getElectricalStimuli();
    if (elecStimulus.length > 0) {
        throw new MappingException("Modles with electrophysiology are not supported for stochastic applications.");
    }
    for (int j = 0; j < structureMappings.length; j++) {
        if (structureMappings[j] instanceof MembraneMapping) {
            MembraneMapping memMapping = (MembraneMapping) structureMappings[j];
            Parameter initialVoltageParm = memMapping.getInitialVoltageParameter();
            try {
                Expression exp = initialVoltageParm.getExpression();
                exp.evaluateConstant();
                varHash.addVariable(newFunctionOrConstant(getMathSymbol(memMapping.getMembrane().getMembraneVoltage(), memMapping.getGeometryClass()), getIdentifierSubstitutions(memMapping.getInitialVoltageParameter().getExpression(), memMapping.getInitialVoltageParameter().getUnitDefinition(), memMapping.getGeometryClass()), memMapping.getGeometryClass()));
            } catch (ExpressionException e) {
                e.printStackTrace(System.out);
                throw new MappingException("Membrane initial voltage: " + initialVoltageParm.getName() + " cannot be evaluated as constant.");
            }
        }
    }
    // 
    for (ReactionRule reactionRule : rrList) {
        // if (reactionRule.getKineticLaw() instanceof LumpedKinetics){
        // throw new RuntimeException("Lumped Kinetics not yet supported for RuleBased Modeling");
        // }
        LocalParameter[] parameters = reactionRule.getKineticLaw().getLocalParameters();
        for (LocalParameter parameter : parameters) {
            // 
            if ((parameter.getRole() == RbmKineticLawParameterType.RuleRate)) {
                continue;
            }
            // 
            if (!reactionRule.isReversible() && parameter.getRole() == RbmKineticLawParameterType.MassActionReverseRate) {
                continue;
            }
            Expression expr = getSubstitutedExpr(parameter.getExpression(), true, false);
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(parameter, geometryClass), getIdentifierSubstitutions(expr, parameter.getUnitDefinition(), geometryClass), geometryClass));
        }
    }
    // the parameter "Size" is already put into mathsymbolmapping in refreshSpeciesContextMapping()
    for (int i = 0; i < structureMappings.length; i++) {
        StructureMapping sm = structureMappings[i];
        StructureMapping.StructureMappingParameter parm = sm.getParameterFromRole(StructureMapping.ROLE_Size);
        if (parm.getExpression() != null) {
            try {
                double value = parm.getExpression().evaluateConstant();
                varHash.addVariable(new Constant(getMathSymbol(parm, sm.getGeometryClass()), new Expression(value)));
            } catch (ExpressionException e) {
                // varHash.addVariable(new Function(getMathSymbol0(parm,sm),getIdentifierSubstitutions(parm.getExpression(),parm.getUnitDefinition(),sm)));
                e.printStackTrace(System.out);
                throw new MappingException("Size of structure:" + sm.getNameScope().getName() + " cannot be evaluated as constant.");
            }
        }
    }
    SpeciesContextSpec[] speciesContextSpecs = getSimulationContext().getReactionContext().getSpeciesContextSpecs();
    addInitialConditions(domain, speciesContextSpecs, varHash);
    // 
    if (simContext.getGeometryContext().getGeometry() != null) {
        try {
            mathDesc.setGeometry(simContext.getGeometryContext().getGeometry());
        } catch (java.beans.PropertyVetoException e) {
            e.printStackTrace(System.out);
            throw new MappingException("failure setting geometry " + e.getMessage());
        }
    } else {
        throw new MappingException("Geometry must be defined in Application " + simContext.getName());
    }
    // 
    // create subDomains
    // 
    SubVolume subVolume = simContext.getGeometry().getGeometrySpec().getSubVolumes()[0];
    SubDomain subDomain = new CompartmentSubDomain(subVolume.getName(), 0);
    mathDesc.addSubDomain(subDomain);
    // 
    // define all molecules and unique species patterns (add molecules to mathDesc and speciesPatterns to varHash).
    // 
    HashMap<SpeciesPattern, VolumeParticleSpeciesPattern> speciesPatternMap = addSpeciesPatterns(domain, rrList);
    HashSet<VolumeParticleSpeciesPattern> uniqueParticleSpeciesPatterns = new HashSet<>(speciesPatternMap.values());
    for (VolumeParticleSpeciesPattern volumeParticleSpeciesPattern : uniqueParticleSpeciesPatterns) {
        varHash.addVariable(volumeParticleSpeciesPattern);
    }
    // 
    // define observables (those explicitly declared and those corresponding to seed species.
    // 
    List<ParticleObservable> observables = addObservables(geometryClass, domain, speciesPatternMap);
    for (ParticleObservable particleObservable : observables) {
        varHash.addVariable(particleObservable);
    }
    try {
        addParticleJumpProcesses(varHash, geometryClass, subDomain, speciesPatternMap);
    } catch (PropertyVetoException e1) {
        e1.printStackTrace();
        throw new MappingException(e1.getMessage(), e1);
    }
    // 
    for (int i = 0; i < fieldMathMappingParameters.length; i++) {
        if (fieldMathMappingParameters[i] instanceof UnitFactorParameter || fieldMathMappingParameters[i] instanceof ObservableConcentrationParameter) {
            varHash.addVariable(newFunctionOrConstant(getMathSymbol(fieldMathMappingParameters[i], geometryClass), getIdentifierSubstitutions(fieldMathMappingParameters[i].getExpression(), fieldMathMappingParameters[i].getUnitDefinition(), geometryClass), fieldMathMappingParameters[i].getGeometryClass()));
        }
    }
    // 
    // set Variables to MathDescription all at once with the order resolved by "VariableHash"
    // 
    mathDesc.setAllVariables(varHash.getAlphabeticallyOrderedVariables());
    // 
    for (SpeciesContext sc : model.getSpeciesContexts()) {
        if (!sc.hasSpeciesPattern()) {
            throw new MappingException("species " + sc.getName() + " has no molecular pattern");
        }
        VolumeParticleSpeciesPattern volumeParticleSpeciesPattern = speciesPatternMap.get(sc.getSpeciesPattern());
        ArrayList<ParticleInitialCondition> particleInitialConditions = new ArrayList<ParticleProperties.ParticleInitialCondition>();
        // initial conditions from scs
        SpeciesContextSpec scs = simContext.getReactionContext().getSpeciesContextSpec(sc);
        Parameter initialCountParameter = scs.getInitialCountParameter();
        Expression e = getIdentifierSubstitutions(new Expression(initialCountParameter, getNameScope()), initialCountParameter.getUnitDefinition(), geometryClass);
        particleInitialConditions.add(new ParticleInitialConditionCount(e, new Expression(0.0), new Expression(0.0), new Expression(0.0)));
        ParticleProperties particleProperies = new ParticleProperties(volumeParticleSpeciesPattern, new Expression(0.0), new Expression(0.0), new Expression(0.0), new Expression(0.0), particleInitialConditions);
        subDomain.addParticleProperties(particleProperies);
    }
    // 
    for (int i = 0; i < fieldMathMappingParameters.length; i++) {
        if (fieldMathMappingParameters[i] instanceof UnitFactorParameter) {
            Variable variable = newFunctionOrConstant(getMathSymbol(fieldMathMappingParameters[i], geometryClass), getIdentifierSubstitutions(fieldMathMappingParameters[i].getExpression(), fieldMathMappingParameters[i].getUnitDefinition(), geometryClass), fieldMathMappingParameters[i].getGeometryClass());
            if (mathDesc.getVariable(variable.getName()) == null) {
                mathDesc.addVariable(variable);
            }
        }
        if (fieldMathMappingParameters[i] instanceof ObservableConcentrationParameter) {
            Variable variable = newFunctionOrConstant(getMathSymbol(fieldMathMappingParameters[i], geometryClass), getIdentifierSubstitutions(fieldMathMappingParameters[i].getExpression(), fieldMathMappingParameters[i].getUnitDefinition(), geometryClass), fieldMathMappingParameters[i].getGeometryClass());
            if (mathDesc.getVariable(variable.getName()) == null) {
                mathDesc.addVariable(variable);
            }
        }
    }
    if (!mathDesc.isValid()) {
        System.out.println(mathDesc.getVCML_database());
        throw new MappingException("generated an invalid mathDescription: " + mathDesc.getWarning());
    }
}
Also used : MathDescription(cbit.vcell.math.MathDescription) ArrayList(java.util.ArrayList) SpeciesContext(cbit.vcell.model.SpeciesContext) ExpressionException(cbit.vcell.parser.ExpressionException) PropertyVetoException(java.beans.PropertyVetoException) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) SubDomain(cbit.vcell.math.SubDomain) SubVolume(cbit.vcell.geometry.SubVolume) HashSet(java.util.HashSet) ModelException(cbit.vcell.model.ModelException) VolumeParticleSpeciesPattern(cbit.vcell.math.VolumeParticleSpeciesPattern) PropertyVetoException(java.beans.PropertyVetoException) ModelParameter(cbit.vcell.model.Model.ModelParameter) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) ParticleInitialCondition(cbit.vcell.math.ParticleProperties.ParticleInitialCondition) ParticleProperties(cbit.vcell.math.ParticleProperties) VolumeParticleObservable(cbit.vcell.math.VolumeParticleObservable) ParticleObservable(cbit.vcell.math.ParticleObservable) CompartmentSubDomain(cbit.vcell.math.CompartmentSubDomain) SubDomain(cbit.vcell.math.SubDomain) Domain(cbit.vcell.math.Variable.Domain) GeometryClass(cbit.vcell.geometry.GeometryClass) VolumeParticleVariable(cbit.vcell.math.VolumeParticleVariable) ParticleVariable(cbit.vcell.math.ParticleVariable) StochVolVariable(cbit.vcell.math.StochVolVariable) Variable(cbit.vcell.math.Variable) VariableHash(cbit.vcell.math.VariableHash) MacroscopicRateConstant(cbit.vcell.math.MacroscopicRateConstant) Constant(cbit.vcell.math.Constant) UnresolvedParameter(cbit.vcell.mapping.ParameterContext.UnresolvedParameter) VolumeParticleSpeciesPattern(cbit.vcell.math.VolumeParticleSpeciesPattern) SpeciesPattern(org.vcell.model.rbm.SpeciesPattern) Structure(cbit.vcell.model.Structure) StochVolVariable(cbit.vcell.math.StochVolVariable) ReactionRule(cbit.vcell.model.ReactionRule) LocalParameter(cbit.vcell.mapping.ParameterContext.LocalParameter) Expression(cbit.vcell.parser.Expression) Model(cbit.vcell.model.Model) Parameter(cbit.vcell.model.Parameter) UnresolvedParameter(cbit.vcell.mapping.ParameterContext.UnresolvedParameter) LocalParameter(cbit.vcell.mapping.ParameterContext.LocalParameter) ModelParameter(cbit.vcell.model.Model.ModelParameter) ParticleInitialConditionCount(cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)

Aggregations

ParticleInitialConditionCount (cbit.vcell.math.ParticleProperties.ParticleInitialConditionCount)6 ParticleInitialCondition (cbit.vcell.math.ParticleProperties.ParticleInitialCondition)5 CompartmentSubDomain (cbit.vcell.math.CompartmentSubDomain)4 ParticleProperties (cbit.vcell.math.ParticleProperties)4 MathException (cbit.vcell.math.MathException)3 ParticleInitialConditionConcentration (cbit.vcell.math.ParticleProperties.ParticleInitialConditionConcentration)3 SubDomain (cbit.vcell.math.SubDomain)3 Expression (cbit.vcell.parser.Expression)3 ExpressionException (cbit.vcell.parser.ExpressionException)3 GeometryClass (cbit.vcell.geometry.GeometryClass)2 SubVolume (cbit.vcell.geometry.SubVolume)2 Constant (cbit.vcell.math.Constant)2 MacroscopicRateConstant (cbit.vcell.math.MacroscopicRateConstant)2 MathDescription (cbit.vcell.math.MathDescription)2 MembraneSubDomain (cbit.vcell.math.MembraneSubDomain)2 ParticleVariable (cbit.vcell.math.ParticleVariable)2 Variable (cbit.vcell.math.Variable)2 Domain (cbit.vcell.math.Variable.Domain)2 VariableHash (cbit.vcell.math.VariableHash)2 VolumeParticleSpeciesPattern (cbit.vcell.math.VolumeParticleSpeciesPattern)2