Example 41 with SymbolTableEntry
use of cbit.vcell.parser.SymbolTableEntry 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 42 with SymbolTableEntry
use of cbit.vcell.parser.SymbolTableEntry in project vcell by virtualcell.
the class DataSetControllerImpl method getSpecialTimeSeriesValues.
private TimeSeriesJobResults getSpecialTimeSeriesValues(OutputContext outputContext, VCDataIdentifier vcdID, TimeSeriesJobSpec timeSeriesJobSpec, TimeInfo timeInfo) throws Exception {
String[] variableNames = timeSeriesJobSpec.getVariableNames();
CartesianMesh mesh = getMesh(vcdID);
// Automatically 'special' (non-optimized timedata retrieval) if isAllowOptimizedTimeDataRetrieval() == false
boolean bIsSpecial = !isAllowOptimizedTimeDataRetrieval();
if (!bIsSpecial) {
VCData simData = getVCData(vcdID);
//
// Gradient and FieldData functions are special.
// They have to be evaluated using the 'full data' method using evaluateFunction(...).
// They cannot be evaluated using the fast findFunctionIndexes(...) method.
// Also if the 'roi' is a significant fraction of the whole dataset then
// the 'full data' method of evaluation is more efficient
// a guess for best efficiency
final double SIGNIFICANT_ROI_FRACTION = .2;
final int ABSOLUTE_SIZE_LIMIT = 10000;
for (int i = 0; i < variableNames.length; i += 1) {
DataSetIdentifier dsi = (DataSetIdentifier) simData.getEntry(variableNames[i]);
if (dsi.getVariableType().equals(VariableType.VOLUME)) {
if (timeSeriesJobSpec.getIndices()[i].length > mesh.getNumVolumeElements() * SIGNIFICANT_ROI_FRACTION) {
bIsSpecial = true;
break;
}
} else if (dsi.getVariableType().equals(VariableType.MEMBRANE)) {
if (timeSeriesJobSpec.getIndices()[i].length > mesh.getNumMembraneElements() * SIGNIFICANT_ROI_FRACTION) {
bIsSpecial = true;
break;
}
}
AnnotatedFunction functionFromVarName = getFunction(outputContext, vcdID, variableNames[i]);
if (functionFromVarName != null) {
FieldFunctionArguments[] fieldFunctionArgumentsArr = FieldUtilities.getFieldFunctionArguments(functionFromVarName.getExpression());
if (hasGradient(functionFromVarName.getExpression()) || (fieldFunctionArgumentsArr != null && fieldFunctionArgumentsArr.length > 0)) {
bIsSpecial = true;
break;
}
// check function absolute size limit
Expression exp = functionFromVarName.getExpression();
String[] funcSymbols = exp.getSymbols();
int varCount = 0;
if (funcSymbols != null) {
for (int j = 0; j < funcSymbols.length; j++) {
SymbolTableEntry ste = exp.getSymbolBinding(funcSymbols[j]);
if (ste instanceof DataSetIdentifier) {
varCount += 1;
}
}
}
varCount = Math.max(varCount, 1);
if (varCount * timeSeriesJobSpec.getIndices()[i].length > ABSOLUTE_SIZE_LIMIT) {
bIsSpecial = true;
break;
}
} else if (timeSeriesJobSpec.getIndices()[i].length > ABSOLUTE_SIZE_LIMIT) {
bIsSpecial = true;
break;
}
}
}
if (!bIsSpecial) {
return null;
}
TimeSeriesJobResults tsjr = null;
if (timeSeriesJobSpec.isCalcTimeStats()) {
throw new RuntimeException("Time Stats Not yet implemented for 'special' data");
} else if (timeSeriesJobSpec.isCalcSpaceStats()) {
// Get spatial statistics at each time point
SpatialStatsInfo ssi = calcSpatialStatsInfo(outputContext, timeSeriesJobSpec, vcdID);
double[][] /*time*/
argMin = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[][] argMax = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[][] argUnweightedMean = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[][] argWeightedMean = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[][] argUnweightedSum = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[][] argWeightedSum = new double[variableNames.length][timeInfo.desiredTimeValues.length];
double[] /*varName*/
argTotalSpace = new double[variableNames.length];
double[][][] indicesForVarForOneTimepoint = new double[1][][];
for (int varNameIndex = 0; varNameIndex < variableNames.length; varNameIndex += 1) {
int[] dataIndices = timeSeriesJobSpec.getIndices()[varNameIndex];
indicesForVarForOneTimepoint[0] = new double[dataIndices.length + 1][1];
for (int timeIndex = 0; timeIndex < timeInfo.desiredTimeValues.length; timeIndex += 1) {
indicesForVarForOneTimepoint[0][0] = new double[] { timeInfo.desiredTimeValues[timeIndex] };
int num = varNameIndex * timeInfo.desiredTimeValues.length + timeIndex;
int denom = variableNames.length * timeInfo.desiredTimeValues.length;
double progressTime = 100.0 * (double) num / (double) denom;
fireDataJobEventIfNecessary(timeSeriesJobSpec.getVcDataJobID(), MessageEvent.DATA_PROGRESS, vcdID, new Double(progressTime), null, null);
SimDataBlock simDatablock = getSimDataBlock(outputContext, vcdID, variableNames[varNameIndex], timeInfo.desiredTimeValues[timeIndex]);
double[] data = simDatablock.getData();
// Put indices in format expected by calcStats (SHOULD BE CHANGED)
for (int dataIndex = 0; dataIndex < dataIndices.length; dataIndex += 1) {
indicesForVarForOneTimepoint[0][dataIndex + 1][0] = data[dataIndices[dataIndex]];
}
if (timeSeriesJobSpec.getCrossingMembraneIndices() != null && timeSeriesJobSpec.getCrossingMembraneIndices().length > 0) {
adjustMembraneAdjacentVolumeValues(outputContext, indicesForVarForOneTimepoint[0], true, simDatablock, timeSeriesJobSpec.getIndices()[varNameIndex], timeSeriesJobSpec.getCrossingMembraneIndices()[varNameIndex], vcdID, variableNames[varNameIndex], mesh, timeInfo);
}
tsjr = calculateStatisticsFromWhole(timeSeriesJobSpec, indicesForVarForOneTimepoint, indicesForVarForOneTimepoint[0][0], ssi);
argMin[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getMinimums()[0][0];
argMax[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getMaximums()[0][0];
argUnweightedMean[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getUnweightedMean()[0][0];
if (((TSJobResultsSpaceStats) tsjr).getWeightedMean() == null) {
argWeightedMean = null;
} else {
argWeightedMean[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getWeightedMean()[0][0];
}
argUnweightedSum[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getUnweightedSum()[0][0];
if (((TSJobResultsSpaceStats) tsjr).getWeightedSum() == null) {
argWeightedSum = null;
} else {
argWeightedSum[varNameIndex][timeIndex] = ((TSJobResultsSpaceStats) tsjr).getWeightedSum()[0][0];
}
if (((TSJobResultsSpaceStats) tsjr).getTotalSpace() == null) {
argTotalSpace = null;
} else {
argTotalSpace[varNameIndex] = ((TSJobResultsSpaceStats) tsjr).getTotalSpace()[0];
}
}
}
tsjr = new TSJobResultsSpaceStats(timeSeriesJobSpec.getVariableNames(), timeSeriesJobSpec.getIndices(), timeInfo.desiredTimeValues, argMin, argMax, argUnweightedMean, argWeightedMean, argUnweightedSum, argWeightedSum, argTotalSpace);
} else {
// Get the values for for all the variables and indices
double[][][] varIndicesTimesArr = new double[variableNames.length][][];
for (int varNameIndex = 0; varNameIndex < variableNames.length; varNameIndex += 1) {
int[] dataIndices = timeSeriesJobSpec.getIndices()[varNameIndex];
varIndicesTimesArr[varNameIndex] = new double[dataIndices.length + 1][timeInfo.desiredTimeValues.length];
varIndicesTimesArr[varNameIndex][0] = timeInfo.desiredTimeValues;
for (int timeIndex = 0; timeIndex < timeInfo.desiredTimeValues.length; timeIndex += 1) {
int num = varNameIndex * timeInfo.desiredTimeValues.length + timeIndex;
int denom = variableNames.length * timeInfo.desiredTimeValues.length;
double progressTime = 100.0 * (double) num / (double) denom;
fireDataJobEventIfNecessary(timeSeriesJobSpec.getVcDataJobID(), MessageEvent.DATA_PROGRESS, vcdID, new Double(progressTime), null, null);
SimDataBlock simDatablock = getSimDataBlock(outputContext, vcdID, variableNames[varNameIndex], timeInfo.desiredTimeValues[timeIndex]);
double[] data = simDatablock.getData();
for (int dataIndex = 0; dataIndex < dataIndices.length; dataIndex += 1) {
varIndicesTimesArr[varNameIndex][dataIndex + 1][timeIndex] = data[dataIndices[dataIndex]];
}
if (timeSeriesJobSpec.getCrossingMembraneIndices() != null && timeSeriesJobSpec.getCrossingMembraneIndices().length > 0) {
adjustMembraneAdjacentVolumeValues(outputContext, varIndicesTimesArr[varNameIndex], true, simDatablock, timeSeriesJobSpec.getIndices()[varNameIndex], timeSeriesJobSpec.getCrossingMembraneIndices()[varNameIndex], vcdID, variableNames[varNameIndex], mesh, timeInfo);
}
}
}
tsjr = new TSJobResultsNoStats(timeSeriesJobSpec.getVariableNames(), timeSeriesJobSpec.getIndices(), timeInfo.desiredTimeValues, varIndicesTimesArr);
}
return tsjr;
}
Also used :
FieldFunctionArguments(cbit.vcell.field.FieldFunctionArguments)
TSJobResultsSpaceStats(org.vcell.util.document.TSJobResultsSpaceStats)
CartesianMesh(cbit.vcell.solvers.CartesianMesh)
SymbolTableEntry(cbit.vcell.parser.SymbolTableEntry)
Expression(cbit.vcell.parser.Expression)
TimeSeriesJobResults(org.vcell.util.document.TimeSeriesJobResults)
TSJobResultsNoStats(org.vcell.util.document.TSJobResultsNoStats)
AnnotatedFunction(cbit.vcell.solver.AnnotatedFunction)
Example 43 with SymbolTableEntry
use of cbit.vcell.parser.SymbolTableEntry in project vcell by virtualcell.
the class DataSetControllerImpl method fieldFunctionSubstitution.
private Expression fieldFunctionSubstitution(OutputContext outputContext, final VCDataIdentifier vcdID, Expression functionExpression) throws ExpressionException, DataAccessException, IOException, MathException {
SimResampleInfoProvider simResampleInfoProvider = null;
Expression origExpression = new Expression(functionExpression);
if (vcdID instanceof VCSimulationDataIdentifier) {
simResampleInfoProvider = ((VCSimulationDataIdentifier) vcdID);
} else if (vcdID instanceof VCSimulationDataIdentifierOldStyle) {
simResampleInfoProvider = ((VCSimulationDataIdentifierOldStyle) vcdID);
} else if (vcdID instanceof ExternalDataIdentifier) {
simResampleInfoProvider = ((ExternalDataIdentifier) vcdID);
} else {
return origExpression;
}
FieldFunctionArguments[] fieldfuncArgumentsArr = FieldUtilities.getFieldFunctionArguments(origExpression);
if (fieldfuncArgumentsArr == null || fieldfuncArgumentsArr.length == 0) {
return origExpression;
}
String[] origSymbols = origExpression.getSymbols();
Vector<SymbolTableEntry> originalSymbolTablEntrryV = new Vector<SymbolTableEntry>();
for (int i = 0; origSymbols != null && i < origSymbols.length; i++) {
if (!originalSymbolTablEntrryV.contains(origExpression.getSymbolBinding(origSymbols[i]))) {
originalSymbolTablEntrryV.add(origExpression.getSymbolBinding(origSymbols[i]));
}
}
Expression exp = new Expression(origExpression);
//
// Handle Field Data Function field(...)
//
double[][] resampledFieldDatas = null;
HashMap<String, Integer> substSymbolIndexH = new HashMap<String, Integer>();
// if(fieldfuncArgumentsArr != null && fieldfuncArgumentsArr.length > 0){
FieldDataIdentifierSpec[] fieldDataIdentifierSpecArr = getFieldDataIdentifierSpecs(fieldfuncArgumentsArr, simResampleInfoProvider.getOwner());
// Substitute Field Data Functions for simple symbols for lookup-------
for (int i = 0; i < fieldfuncArgumentsArr.length; i += 1) {
for (int j = 0; j < fieldDataIdentifierSpecArr.length; j++) {
if (fieldfuncArgumentsArr[i].equals(fieldDataIdentifierSpecArr[j].getFieldFuncArgs())) {
String substFieldName = fieldfuncArgumentsArr[i].getFieldName() + "_" + fieldfuncArgumentsArr[i].getVariableName() + "_" + fieldfuncArgumentsArr[i].getTime().evaluateConstant();
substFieldName = TokenMangler.fixTokenStrict(substFieldName);
if (exp.hasSymbol(substFieldName)) {
throw new DataAccessException("Substitute Field data name is not unique");
}
String fieldFuncString = SimulationData.createCanonicalFieldFunctionSyntax(fieldDataIdentifierSpecArr[j].getExternalDataIdentifier().getName(), fieldfuncArgumentsArr[i].getVariableName(), fieldfuncArgumentsArr[i].getTime().evaluateConstant(), fieldfuncArgumentsArr[i].getVariableType().getTypeName());
exp.substituteInPlace(new Expression(fieldFuncString), new Expression(substFieldName));
substSymbolIndexH.put(substFieldName, i);
break;
}
}
}
// ----------------------------------------------------------------------
boolean[] bResample = new boolean[fieldDataIdentifierSpecArr.length];
Arrays.fill(bResample, true);
writeFieldFunctionData(outputContext, fieldDataIdentifierSpecArr, bResample, getMesh(simResampleInfoProvider), simResampleInfoProvider, getMesh(simResampleInfoProvider).getNumMembraneElements(), FVSolverStandalone.HESM_KEEP_AND_CONTINUE);
resampledFieldDatas = new double[fieldfuncArgumentsArr.length][];
for (int i = 0; i < fieldfuncArgumentsArr.length; i += 1) {
// File resampledFile =
// new File(getUserDir(vcsdID.getOwner()),
// vcsdID.getID()+
// FieldDataIdentifierSpec.getDefaultFieldDataFileNameForSimulation(fieldfuncArgumentsArr[i])
// );
// File resampledFile = new File(getPrimaryUserDir(simResampleInfoProvider.getOwner(), true),
// SimulationData.createCanonicalResampleFileName(
// simResampleInfoProvider, fieldfuncArgumentsArr[i]));
File resampledFile = ((SimulationData) getVCData(simResampleInfoProvider)).getFieldDataFile(simResampleInfoProvider, fieldfuncArgumentsArr[i]);
resampledFieldDatas[i] = DataSet.fetchSimData(fieldfuncArgumentsArr[i].getVariableName(), resampledFile);
}
// }
// Rebind all the symbols
String[] dependentIDs = exp.getSymbols();
VariableSymbolTable varSymbolTable = new VariableSymbolTable();
for (int i = 0; dependentIDs != null && i < dependentIDs.length; i++) {
SymbolTableEntry newSymbolTableEntry = null;
for (int j = 0; j < originalSymbolTablEntrryV.size(); j++) {
if (originalSymbolTablEntrryV.elementAt(j).getName().equals(dependentIDs[i])) {
newSymbolTableEntry = originalSymbolTablEntrryV.elementAt(j);
break;
}
}
if (newSymbolTableEntry == null) {
if (substSymbolIndexH.containsKey(dependentIDs[i])) {
int resampledDataIndex = substSymbolIndexH.get(dependentIDs[i]).intValue();
FieldDataParameterVariable fieldDataParameterVariable = new FieldDataParameterVariable(dependentIDs[i], resampledFieldDatas[resampledDataIndex]);
newSymbolTableEntry = fieldDataParameterVariable;
}
}
if (newSymbolTableEntry == null) {
throw new DataAccessException("Field Data Couldn't find substituted expression while evaluating function");
}
varSymbolTable.addVar(newSymbolTableEntry);
}
exp.bindExpression(varSymbolTable);
return exp;
}
Also used :
HashMap(java.util.HashMap)
SymbolTableEntry(cbit.vcell.parser.SymbolTableEntry)
ExternalDataIdentifier(org.vcell.util.document.ExternalDataIdentifier)
VariableSymbolTable(cbit.vcell.parser.VariableSymbolTable)
Vector(java.util.Vector)
DataAccessException(org.vcell.util.DataAccessException)
FieldDataParameterVariable(cbit.vcell.field.FieldDataParameterVariable)
FieldFunctionArguments(cbit.vcell.field.FieldFunctionArguments)
SimResampleInfoProvider(org.vcell.util.document.SimResampleInfoProvider)
VCSimulationDataIdentifier(cbit.vcell.solver.VCSimulationDataIdentifier)
Expression(cbit.vcell.parser.Expression)
FieldDataIdentifierSpec(cbit.vcell.field.FieldDataIdentifierSpec)
VCSimulationDataIdentifierOldStyle(cbit.vcell.solver.VCSimulationDataIdentifierOldStyle)
ZipFile(org.apache.commons.compress.archivers.zip.ZipFile)
File(java.io.File)
Example 44 with SymbolTableEntry
use of cbit.vcell.parser.SymbolTableEntry in project vcell by virtualcell.
the class SimulationSymbolTable method hasTimeVaryingDiffusionOrAdvection.
public boolean hasTimeVaryingDiffusionOrAdvection(Variable variable) throws MathException, ExpressionException {
Enumeration<SubDomain> enum1 = simulation.getMathDescription().getSubDomains();
while (enum1.hasMoreElements()) {
SubDomain subDomain = enum1.nextElement();
Equation equation = subDomain.getEquation(variable);
//
if (equation instanceof PdeEquation) {
Vector<Expression> spatialExpressionList = new Vector<Expression>();
spatialExpressionList.add(((PdeEquation) equation).getDiffusionExpression());
if (((PdeEquation) equation).getVelocityX() != null) {
spatialExpressionList.add(((PdeEquation) equation).getVelocityX());
}
if (((PdeEquation) equation).getVelocityY() != null) {
spatialExpressionList.add(((PdeEquation) equation).getVelocityY());
}
if (((PdeEquation) equation).getVelocityZ() != null) {
spatialExpressionList.add(((PdeEquation) equation).getVelocityZ());
}
for (int i = 0; i < spatialExpressionList.size(); i++) {
Expression spatialExp = spatialExpressionList.elementAt(i);
spatialExp = substituteFunctions(spatialExp);
String[] symbols = spatialExp.getSymbols();
if (symbols != null) {
for (int j = 0; j < symbols.length; j++) {
SymbolTableEntry entry = spatialExp.getSymbolBinding(symbols[j]);
if (entry instanceof ReservedVariable) {
if (((ReservedVariable) entry).isTIME()) {
return true;
}
}
if (entry instanceof VolVariable) {
return true;
}
if (entry instanceof VolumeRegionVariable) {
return true;
}
if (entry instanceof MemVariable || entry instanceof MembraneRegionVariable) {
return true;
}
}
}
}
}
}
return false;
}
Also used :
MembraneRegionVariable(cbit.vcell.math.MembraneRegionVariable)
VolVariable(cbit.vcell.math.VolVariable)
PdeEquation(cbit.vcell.math.PdeEquation)
Equation(cbit.vcell.math.Equation)
SubDomain(cbit.vcell.math.SubDomain)
MembraneSubDomain(cbit.vcell.math.MembraneSubDomain)
PdeEquation(cbit.vcell.math.PdeEquation)
VolumeRegionVariable(cbit.vcell.math.VolumeRegionVariable)
SymbolTableEntry(cbit.vcell.parser.SymbolTableEntry)
ReservedVariable(cbit.vcell.math.ReservedVariable)
MemVariable(cbit.vcell.math.MemVariable)
Expression(cbit.vcell.parser.Expression)
Vector(java.util.Vector)
Example 45 with SymbolTableEntry
use of cbit.vcell.parser.SymbolTableEntry in project vcell by virtualcell.
the class CVodeFileWriter method writeEquations.
/**
* Insert the method's description here.
* Creation date: (3/8/00 10:31:52 PM)
*/
protected String writeEquations(HashMap<Discontinuity, String> discontinuityNameMap) throws MathException, ExpressionException {
StringBuffer sb = new StringBuffer();
for (int i = 0; i < getStateVariableCount(); i++) {
StateVariable stateVar = getStateVariable(i);
Expression rateExpr = new Expression(stateVar.getRateExpression());
Expression initExpr = new Expression(stateVar.getInitialRateExpression());
initExpr = MathUtilities.substituteFunctions(initExpr, varsSymbolTable).flatten();
initExpr.substituteInPlace(new Expression("t"), new Expression(0.0));
String[] symbols0 = initExpr.getSymbols();
if (symbols0 != null) {
for (String symbol : symbols0) {
SymbolTableEntry ste = initExpr.getSymbolBinding(symbol);
if (!ste.equals(ReservedVariable.X) && !ste.equals(ReservedVariable.Y) && !ste.equals(ReservedVariable.Z)) {
throw new MathException("Variables are not allowed in initial condition.\nInitial condition of variable:" + stateVar.getVariable().getName() + " has variable(" + symbol + ") in expression.");
}
}
}
rateExpr = MathUtilities.substituteFunctions(rateExpr, varsSymbolTable).flatten();
Vector<Discontinuity> v = rateExpr.getDiscontinuities();
for (Discontinuity od : v) {
od = getSubsitutedAndFlattened(od, varsSymbolTable);
String dname = discontinuityNameMap.get(od);
if (dname == null) {
dname = ROOT_VARIABLE_PREFIX + discontinuityNameMap.size();
discontinuityNameMap.put(od, dname);
}
rateExpr.substituteInPlace(od.getDiscontinuityExp(), new Expression("(" + dname + "==1)"));
}
sb.append("ODE " + stateVar.getVariable().getName() + " INIT " + initExpr.flatten().infix() + ";\n\t RATE " + rateExpr.flatten().infix() + ";\n");
}
return sb.toString();
}
Also used :
Discontinuity(cbit.vcell.parser.Discontinuity)
SymbolTableEntry(cbit.vcell.parser.SymbolTableEntry)
Expression(cbit.vcell.parser.Expression)
MathException(cbit.vcell.math.MathException)
Aggregations
SymbolTableEntry (cbit.vcell.parser.SymbolTableEntry)115
Expression (cbit.vcell.parser.Expression)50
ExpressionException (cbit.vcell.parser.ExpressionException)20
Vector (java.util.Vector)20
ArrayList (java.util.ArrayList)19
SpeciesContext (cbit.vcell.model.SpeciesContext)18
ModelParameter (cbit.vcell.model.Model.ModelParameter)14
PropertyVetoException (java.beans.PropertyVetoException)14
VCUnitDefinition (cbit.vcell.units.VCUnitDefinition)13
Model (cbit.vcell.model.Model)12
KineticsParameter (cbit.vcell.model.Kinetics.KineticsParameter)11
HashMap (java.util.HashMap)11
SimulationContext (cbit.vcell.mapping.SimulationContext)10
Variable (cbit.vcell.math.Variable)10
LocalParameter (cbit.vcell.mapping.ParameterContext.LocalParameter)9
SpeciesContextSpec (cbit.vcell.mapping.SpeciesContextSpec)9
Parameter (cbit.vcell.model.Parameter)9
SingleXPlot2D (cbit.plot.SingleXPlot2D)8
MathException (cbit.vcell.math.MathException)8
ReservedVariable (cbit.vcell.math.ReservedVariable)8
