use of cbit.vcell.solver.TimeBounds in project vcell by virtualcell.
the class VCellSBMLSolver method solveVCell.
public File solveVCell(String filePrefix, File outDir, String sbmlFileName, SimSpec testSpec) throws IOException, SolverException, SbmlException {
try {
cbit.util.xml.VCLogger logger = new LocalLogger();
//
// Instantiate an SBMLImporter to get the speciesUnitsHash - to compute the conversion factor from VC->SB species units.
// and import SBML (sbml->bioModel)
org.vcell.sbml.vcell.SBMLImporter sbmlImporter = new org.vcell.sbml.vcell.SBMLImporter(sbmlFileName, logger, false);
BioModel bioModel = sbmlImporter.getBioModel();
if (bRoundTrip) {
// Round trip the bioModel (bioModel->sbml->bioModel).
// export bioModel as sbml and save
String vcml_sbml = cbit.vcell.xml.XmlHelper.exportSBML(bioModel, 2, 1, 0, false, bioModel.getSimulationContext(0), null);
// re-import bioModel from exported sbml
XMLSource vcml_sbml_Src = new XMLSource(vcml_sbml);
BioModel newBioModel = (BioModel) XmlHelper.importSBML(logger, vcml_sbml_Src, false);
// have rest of code use the round-tripped biomodel
bioModel = newBioModel;
}
//
// select only Application, generate math, and create a single Simulation.
//
SimulationContext simContext = bioModel.getSimulationContext(0);
MathMapping mathMapping = simContext.createNewMathMapping();
MathDescription mathDesc = mathMapping.getMathDescription();
simContext.setMathDescription(mathDesc);
SimulationVersion simVersion = new SimulationVersion(new KeyValue("100"), "unnamed", null, null, null, null, null, null, null, null);
Simulation sim = new Simulation(simVersion, mathDesc);
sim.setName("unnamed");
// if time factor from SBML is not 1 (i.e., it is not in secs but in minutes or hours), convert endTime to min/hr as : endTime*timeFactor
// double endTime = testSpec.getEndTime()*timeFactor;
double endTime = testSpec.getEndTime();
sim.getSolverTaskDescription().setTimeBounds(new TimeBounds(0, endTime));
TimeStep timeStep = new TimeStep();
sim.getSolverTaskDescription().setTimeStep(new TimeStep(timeStep.getMinimumTimeStep(), timeStep.getDefaultTimeStep(), endTime / 10000));
sim.getSolverTaskDescription().setOutputTimeSpec(new UniformOutputTimeSpec((endTime - 0) / testSpec.getNumTimeSteps()));
sim.getSolverTaskDescription().setErrorTolerance(new ErrorTolerance(testSpec.getAbsTolerance(), testSpec.getRelTolerance()));
// sim.getSolverTaskDescription().setErrorTolerance(new ErrorTolerance(1e-10, 1e-12));
// Generate .idaInput string
File idaInputFile = new File(outDir, filePrefix + SimDataConstants.IDAINPUT_DATA_EXTENSION);
PrintWriter idaPW = new java.io.PrintWriter(idaInputFile);
SimulationJob simJob = new SimulationJob(sim, 0, null);
SimulationTask simTask = new SimulationTask(simJob, 0);
IDAFileWriter idaFileWriter = new IDAFileWriter(idaPW, simTask);
idaFileWriter.write();
idaPW.close();
// use the idastandalone solver
File idaOutputFile = new File(outDir, filePrefix + SimDataConstants.IDA_DATA_EXTENSION);
// String sundialsSolverExecutable = "C:\\Developer\\Eclipse\\workspace\\VCell 4.8\\SundialsSolverStandalone_NoMessaging.exe";
String executableName = null;
try {
executableName = SolverUtilities.getExes(SolverDescription.IDA)[0].getAbsolutePath();
} catch (IOException e) {
throw new RuntimeException("failed to get executable for solver " + SolverDescription.IDA.getDisplayLabel() + ": " + e.getMessage(), e);
}
Executable executable = new Executable(new String[] { executableName, idaInputFile.getAbsolutePath(), idaOutputFile.getAbsolutePath() });
executable.start();
/* // Generate .cvodeInput string
File cvodeFile = new File(outDir,filePrefix+SimDataConstants.CVODEINPUT_DATA_EXTENSION);
PrintWriter cvodePW = new java.io.PrintWriter(cvodeFile);
SimulationJob simJob = new SimulationJob(sim, 0, null);
CVodeFileWriter cvodeFileWriter = new CVodeFileWriter(cvodePW, simJob);
cvodeFileWriter.write();
cvodePW.close();
// use the cvodeStandalone solver
File cvodeOutputFile = new File(outDir,filePrefix+SimDataConstants.IDA_DATA_EXTENSION);
String sundialsSolverExecutable = PropertyLoader.getRequiredProperty(PropertyLoader.sundialsSolverExecutableProperty);
Executable executable = new Executable(new String[]{sundialsSolverExecutable, cvodeFile.getAbsolutePath(), cvodeOutputFile.getAbsolutePath()});
executable.start();
*/
// get the result
ODESolverResultSet odeSolverResultSet = getODESolverResultSet(simJob, idaOutputFile.getPath());
// remove CVOde input and output files ??
idaInputFile.delete();
idaOutputFile.delete();
//
// print header
//
File outputFile = new File(outDir, "results" + filePrefix + ".csv");
java.io.PrintStream outputStream = new java.io.PrintStream(new java.io.BufferedOutputStream(new java.io.FileOutputStream(outputFile)));
outputStream.print("time");
for (int i = 0; i < testSpec.getVarsList().length; i++) {
outputStream.print("," + testSpec.getVarsList()[i]);
}
outputStream.println();
//
// extract data for time and species
//
double[][] data = new double[testSpec.getVarsList().length + 1][];
int column = odeSolverResultSet.findColumn("t");
data[0] = odeSolverResultSet.extractColumn(column);
int origDataLength = data[0].length;
for (int i = 0; i < testSpec.getVarsList().length; i++) {
column = odeSolverResultSet.findColumn(testSpec.getVarsList()[i]);
if (column == -1) {
Variable var = simJob.getSimulationSymbolTable().getVariable(testSpec.getVarsList()[i]);
data[i + 1] = new double[data[0].length];
if (var instanceof cbit.vcell.math.Constant) {
double value = ((cbit.vcell.math.Constant) var).getExpression().evaluateConstant();
for (int j = 0; j < data[i + 1].length; j++) {
data[i + 1][j] = value;
}
} else {
throw new RuntimeException("Did not find " + testSpec.getVarsList()[i] + " in simulation");
}
} else {
data[i + 1] = odeSolverResultSet.extractColumn(column);
}
}
//
// for each time, print row
//
int index = 0;
double[] sampleTimes = new double[testSpec.getNumTimeSteps() + 1];
for (int i = 0; i <= testSpec.getNumTimeSteps(); i++) {
sampleTimes[i] = endTime * i / testSpec.getNumTimeSteps();
}
Model vcModel = bioModel.getModel();
ReservedSymbol kMole = vcModel.getKMOLE();
for (int i = 0; i < sampleTimes.length; i++) {
//
while (true) {
//
if (index == odeSolverResultSet.getRowCount() - 1) {
if (data[0][index] == sampleTimes[i]) {
break;
} else {
throw new RuntimeException("sampleTime does not match at last time point");
}
}
//
if (data[0][index + 1] > sampleTimes[i]) {
break;
}
//
// sampleTime must be later in our data list.
//
index++;
}
// if data[0][index] == sampleTime no need to interpolate
if (data[0][index] == sampleTimes[i]) {
// if timeFactor is not 1.0, time is not in seconds (mins or hrs); if timeFactor is 60, divide sampleTime/60; if it is 3600, divide sampleTime/3600.
// if (timeFactor != 1.0) {
// outputStream.print(data[0][index]/timeFactor);
// } else {
outputStream.print(data[0][index]);
// }
for (int j = 0; j < testSpec.getVarsList().length; j++) {
// SBMLImporter.SBVCConcentrationUnits spConcUnits = speciesUnitsHash.get(testSpec.getVarsList()[j]);
// if (spConcUnits != null) {
// VCUnitDefinition sbunits = spConcUnits.getSBConcentrationUnits();
// VCUnitDefinition vcunits = spConcUnits.getVCConcentrationUnits();
// SBMLUnitParameter unitFactor = SBMLUtils.getConcUnitFactor("spConcParam", vcunits, sbunits, kMole);
// outputStream.print("," + data[j + 1][index] * unitFactor.getExpression().evaluateConstant()); //earlier, hack unitfactor = 0.000001
// earlier, hack unitfactor = 0.000001
outputStream.print("," + data[j + 1][index]);
// }
}
// System.out.println("No interpolation needed!");
outputStream.println();
} else {
// if data[0][index] < sampleTime, must interpolate
double fraction = (sampleTimes[i] - data[0][index]) / (data[0][index + 1] - data[0][index]);
// if timeFactor is not 1.0, time is not in seconds (mins or hrs); if timeFactor is 60, divide sampleTime/60; if it is 3600, divide sampleTime/3600.
// if (timeFactor != 1.0) {
// outputStream.print(sampleTimes[i]/timeFactor);
// } else {
outputStream.print(sampleTimes[i]);
// }
for (int j = 0; j < testSpec.getVarsList().length; j++) {
double interpolatedValue = 0.0;
double[] speciesVals = null;
double[] times = null;
// Currently using 2nd order interpolation
if (index == 0) {
// can only do 1st order interpolation
times = new double[] { data[0][index], data[0][index + 1] };
speciesVals = new double[] { data[j + 1][index], data[j + 1][index + 1] };
interpolatedValue = MathTestingUtilities.taylorInterpolation(sampleTimes[i], times, speciesVals);
} else if (index >= 1 && index <= origDataLength - 3) {
double val_1 = Math.abs(sampleTimes[i] - data[0][index - 1]);
double val_2 = Math.abs(sampleTimes[i] - data[0][index + 2]);
if (val_1 < val_2) {
times = new double[] { data[0][index - 1], data[0][index], data[0][index + 1] };
speciesVals = new double[] { data[j + 1][index - 1], data[j + 1][index], data[j + 1][index + 1] };
} else {
times = new double[] { data[0][index], data[0][index + 1], data[0][index + 2] };
speciesVals = new double[] { data[j + 1][index], data[j + 1][index + 1], data[j + 1][index + 2] };
}
interpolatedValue = MathTestingUtilities.taylorInterpolation(sampleTimes[i], times, speciesVals);
} else {
times = new double[] { data[0][index - 1], data[0][index], data[0][index + 1] };
speciesVals = new double[] { data[j + 1][index - 1], data[j + 1][index], data[j + 1][index + 1] };
interpolatedValue = MathTestingUtilities.taylorInterpolation(sampleTimes[i], times, speciesVals);
}
// // Currently using 1st order interpolation
// times = new double[] { data[0][index], data[0][index+1] };
// speciesVals = new double[] { data[j+1][index], data[j+1][index+1] };
// interpolatedValue = taylorInterpolation(sampleTimes[i], times, speciesVals);
// interpolatedValue = interpolatedValue * unitFactor.getExpression().evaluateConstant(); //earlier, hack unitfactor = 0.000001
// System.out.println("Sample time: " + sampleTimes[i] + ", between time[" + index + "]=" + data[0][index]+" and time["+(index+1)+"]="+(data[0][index+1])+", interpolated = "+interpolatedValue);
outputStream.print("," + interpolatedValue);
}
outputStream.println();
}
}
outputStream.close();
return outputFile;
} catch (Exception e) {
e.printStackTrace(System.out);
// File outputFile = new File(outDir,"results" + filePrefix + ".csv");
throw new SolverException(e.getMessage());
}
}
use of cbit.vcell.solver.TimeBounds in project vcell by virtualcell.
the class FRAPStudy method createNewSimBioModel.
public static BioModel createNewSimBioModel(FRAPStudy sourceFrapStudy, Parameter[] params, TimeStep tStep, KeyValue simKey, User owner, int startingIndexForRecovery) throws Exception {
if (owner == null) {
throw new Exception("Owner is not defined");
}
ROI cellROI_2D = sourceFrapStudy.getFrapData().getRoi(FRAPData.VFRAP_ROI_ENUM.ROI_CELL.name());
double df = params[FRAPModel.INDEX_PRIMARY_DIFF_RATE].getInitialGuess();
double ff = params[FRAPModel.INDEX_PRIMARY_FRACTION].getInitialGuess();
double bwmRate = params[FRAPModel.INDEX_BLEACH_MONITOR_RATE].getInitialGuess();
double dc = 0;
double fc = 0;
double bs = 0;
double onRate = 0;
double offRate = 0;
if (params.length == FRAPModel.NUM_MODEL_PARAMETERS_TWO_DIFF) {
dc = params[FRAPModel.INDEX_SECONDARY_DIFF_RATE].getInitialGuess();
fc = params[FRAPModel.INDEX_SECONDARY_FRACTION].getInitialGuess();
} else if (params.length == FRAPModel.NUM_MODEL_PARAMETERS_BINDING) {
dc = params[FRAPModel.INDEX_SECONDARY_DIFF_RATE].getInitialGuess();
fc = params[FRAPModel.INDEX_SECONDARY_FRACTION].getInitialGuess();
bs = params[FRAPModel.INDEX_BINDING_SITE_CONCENTRATION].getInitialGuess();
onRate = params[FRAPModel.INDEX_ON_RATE].getInitialGuess();
offRate = params[FRAPModel.INDEX_OFF_RATE].getInitialGuess();
}
// immobile fraction
double fimm = 1 - ff - fc;
if (fimm < FRAPOptimizationUtils.epsilon && fimm > (0 - FRAPOptimizationUtils.epsilon)) {
fimm = 0;
}
if (fimm < (1 + FRAPOptimizationUtils.epsilon) && fimm > (1 - FRAPOptimizationUtils.epsilon)) {
fimm = 1;
}
Extent extent = sourceFrapStudy.getFrapData().getImageDataset().getExtent();
double[] timeStamps = sourceFrapStudy.getFrapData().getImageDataset().getImageTimeStamps();
TimeBounds timeBounds = new TimeBounds(0.0, timeStamps[timeStamps.length - 1] - timeStamps[startingIndexForRecovery]);
double timeStepVal = timeStamps[startingIndexForRecovery + 1] - timeStamps[startingIndexForRecovery];
int numX = cellROI_2D.getRoiImages()[0].getNumX();
int numY = cellROI_2D.getRoiImages()[0].getNumY();
int numZ = cellROI_2D.getRoiImages().length;
short[] shortPixels = cellROI_2D.getRoiImages()[0].getPixels();
byte[] bytePixels = new byte[numX * numY * numZ];
final byte EXTRACELLULAR_PIXVAL = 0;
final byte CYTOSOL_PIXVAL = 1;
for (int i = 0; i < bytePixels.length; i++) {
if (shortPixels[i] != 0) {
bytePixels[i] = CYTOSOL_PIXVAL;
}
}
VCImage maskImage;
try {
maskImage = new VCImageUncompressed(null, bytePixels, extent, numX, numY, numZ);
} catch (ImageException e) {
e.printStackTrace();
throw new RuntimeException("failed to create mask image for geometry");
}
Geometry geometry = new Geometry("geometry", maskImage);
if (geometry.getGeometrySpec().getNumSubVolumes() != 2) {
throw new Exception("Cell ROI has no ExtraCellular.");
}
int subVolume0PixVal = ((ImageSubVolume) geometry.getGeometrySpec().getSubVolume(0)).getPixelValue();
geometry.getGeometrySpec().getSubVolume(0).setName((subVolume0PixVal == EXTRACELLULAR_PIXVAL ? EXTRACELLULAR_NAME : CYTOSOL_NAME));
int subVolume1PixVal = ((ImageSubVolume) geometry.getGeometrySpec().getSubVolume(1)).getPixelValue();
geometry.getGeometrySpec().getSubVolume(1).setName((subVolume1PixVal == CYTOSOL_PIXVAL ? CYTOSOL_NAME : EXTRACELLULAR_NAME));
geometry.getGeometrySurfaceDescription().updateAll();
BioModel bioModel = new BioModel(null);
bioModel.setName("unnamed");
Model model = new Model("model");
bioModel.setModel(model);
model.addFeature(EXTRACELLULAR_NAME);
Feature extracellular = (Feature) model.getStructure(EXTRACELLULAR_NAME);
model.addFeature(CYTOSOL_NAME);
Feature cytosol = (Feature) model.getStructure(CYTOSOL_NAME);
// Membrane mem = model.addMembrane(EXTRACELLULAR_CYTOSOL_MEM_NAME);
// model.getStructureTopology().setInsideFeature(mem, cytosol);
// model.getStructureTopology().setOutsideFeature(mem, extracellular);
String roiDataName = FRAPStudy.ROI_EXTDATA_NAME;
final int SPECIES_COUNT = 4;
final int FREE_SPECIES_INDEX = 0;
final int BS_SPECIES_INDEX = 1;
final int COMPLEX_SPECIES_INDEX = 2;
final int IMMOBILE_SPECIES_INDEX = 3;
Expression[] diffusionConstants = null;
Species[] species = null;
SpeciesContext[] speciesContexts = null;
Expression[] initialConditions = null;
diffusionConstants = new Expression[SPECIES_COUNT];
species = new Species[SPECIES_COUNT];
speciesContexts = new SpeciesContext[SPECIES_COUNT];
initialConditions = new Expression[SPECIES_COUNT];
// total initial condition
FieldFunctionArguments postBleach_first = new FieldFunctionArguments(roiDataName, "postbleach_first", new Expression(0), VariableType.VOLUME);
FieldFunctionArguments prebleach_avg = new FieldFunctionArguments(roiDataName, "prebleach_avg", new Expression(0), VariableType.VOLUME);
Expression expPostBleach_first = new Expression(postBleach_first.infix());
Expression expPreBleach_avg = new Expression(prebleach_avg.infix());
Expression totalIniCondition = Expression.div(expPostBleach_first, expPreBleach_avg);
// Free Species
diffusionConstants[FREE_SPECIES_INDEX] = new Expression(df);
species[FREE_SPECIES_INDEX] = new Species(FRAPStudy.SPECIES_NAME_PREFIX_MOBILE, "Mobile bleachable species");
speciesContexts[FREE_SPECIES_INDEX] = new SpeciesContext(null, species[FREE_SPECIES_INDEX].getCommonName(), species[FREE_SPECIES_INDEX], cytosol);
initialConditions[FREE_SPECIES_INDEX] = Expression.mult(new Expression(ff), totalIniCondition);
// Immobile Species (No diffusion)
// Set very small diffusion rate on immobile to force evaluation as state variable (instead of FieldData function)
// If left as a function errors occur because functions involving FieldData require a database connection
final String IMMOBILE_DIFFUSION_KLUDGE = "1e-14";
diffusionConstants[IMMOBILE_SPECIES_INDEX] = new Expression(IMMOBILE_DIFFUSION_KLUDGE);
species[IMMOBILE_SPECIES_INDEX] = new Species(FRAPStudy.SPECIES_NAME_PREFIX_IMMOBILE, "Immobile bleachable species");
speciesContexts[IMMOBILE_SPECIES_INDEX] = new SpeciesContext(null, species[IMMOBILE_SPECIES_INDEX].getCommonName(), species[IMMOBILE_SPECIES_INDEX], cytosol);
initialConditions[IMMOBILE_SPECIES_INDEX] = Expression.mult(new Expression(fimm), totalIniCondition);
// BS Species
diffusionConstants[BS_SPECIES_INDEX] = new Expression(IMMOBILE_DIFFUSION_KLUDGE);
species[BS_SPECIES_INDEX] = new Species(FRAPStudy.SPECIES_NAME_PREFIX_BINDING_SITE, "Binding Site species");
speciesContexts[BS_SPECIES_INDEX] = new SpeciesContext(null, species[BS_SPECIES_INDEX].getCommonName(), species[BS_SPECIES_INDEX], cytosol);
initialConditions[BS_SPECIES_INDEX] = Expression.mult(new Expression(bs), totalIniCondition);
// Complex species
diffusionConstants[COMPLEX_SPECIES_INDEX] = new Expression(dc);
species[COMPLEX_SPECIES_INDEX] = new Species(FRAPStudy.SPECIES_NAME_PREFIX_SLOW_MOBILE, "Slower mobile bleachable species");
speciesContexts[COMPLEX_SPECIES_INDEX] = new SpeciesContext(null, species[COMPLEX_SPECIES_INDEX].getCommonName(), species[COMPLEX_SPECIES_INDEX], cytosol);
initialConditions[COMPLEX_SPECIES_INDEX] = Expression.mult(new Expression(fc), totalIniCondition);
// add reactions to species if there is bleachWhileMonitoring rate.
for (int i = 0; i < initialConditions.length; i++) {
model.addSpecies(species[i]);
model.addSpeciesContext(speciesContexts[i]);
// reaction with BMW rate, which should not be applied to binding site
if (!(species[i].getCommonName().equals(FRAPStudy.SPECIES_NAME_PREFIX_BINDING_SITE))) {
SimpleReaction simpleReaction = new SimpleReaction(model, cytosol, speciesContexts[i].getName() + "_bleach", true);
model.addReactionStep(simpleReaction);
simpleReaction.addReactant(speciesContexts[i], 1);
MassActionKinetics massActionKinetics = new MassActionKinetics(simpleReaction);
simpleReaction.setKinetics(massActionKinetics);
KineticsParameter kforward = massActionKinetics.getForwardRateParameter();
simpleReaction.getKinetics().setParameterValue(kforward, new Expression(new Double(bwmRate)));
}
}
// add the binding reaction: F + BS <-> C
SimpleReaction simpleReaction2 = new SimpleReaction(model, cytosol, "reac_binding", true);
model.addReactionStep(simpleReaction2);
simpleReaction2.addReactant(speciesContexts[FREE_SPECIES_INDEX], 1);
simpleReaction2.addReactant(speciesContexts[BS_SPECIES_INDEX], 1);
simpleReaction2.addProduct(speciesContexts[COMPLEX_SPECIES_INDEX], 1);
MassActionKinetics massActionKinetics = new MassActionKinetics(simpleReaction2);
simpleReaction2.setKinetics(massActionKinetics);
KineticsParameter kforward = massActionKinetics.getForwardRateParameter();
KineticsParameter kreverse = massActionKinetics.getReverseRateParameter();
simpleReaction2.getKinetics().setParameterValue(kforward, new Expression(new Double(onRate)));
simpleReaction2.getKinetics().setParameterValue(kreverse, new Expression(new Double(offRate)));
// create simulation context
SimulationContext simContext = new SimulationContext(bioModel.getModel(), geometry);
bioModel.addSimulationContext(simContext);
FeatureMapping cytosolFeatureMapping = (FeatureMapping) simContext.getGeometryContext().getStructureMapping(cytosol);
FeatureMapping extracellularFeatureMapping = (FeatureMapping) simContext.getGeometryContext().getStructureMapping(extracellular);
// Membrane plasmaMembrane = model.getStructureTopology().getMembrane(cytosol, extracellular);
// MembraneMapping plasmaMembraneMapping = (MembraneMapping)simContext.getGeometryContext().getStructureMapping(plasmaMembrane);
SubVolume cytSubVolume = geometry.getGeometrySpec().getSubVolume(CYTOSOL_NAME);
SubVolume exSubVolume = geometry.getGeometrySpec().getSubVolume(EXTRACELLULAR_NAME);
SurfaceClass pmSurfaceClass = geometry.getGeometrySurfaceDescription().getSurfaceClass(exSubVolume, cytSubVolume);
cytosolFeatureMapping.setGeometryClass(cytSubVolume);
extracellularFeatureMapping.setGeometryClass(exSubVolume);
// plasmaMembraneMapping.setGeometryClass(pmSurfaceClass);
cytosolFeatureMapping.getUnitSizeParameter().setExpression(new Expression(1.0));
extracellularFeatureMapping.getUnitSizeParameter().setExpression(new Expression(1.0));
for (int i = 0; i < speciesContexts.length; i++) {
SpeciesContextSpec scs = simContext.getReactionContext().getSpeciesContextSpec(speciesContexts[i]);
scs.getInitialConditionParameter().setExpression(initialConditions[i]);
scs.getDiffusionParameter().setExpression(diffusionConstants[i]);
}
MathMapping mathMapping = simContext.createNewMathMapping();
MathDescription mathDesc = mathMapping.getMathDescription();
// Add total fluorescence as function of mobile(optional: and slower mobile) and immobile fractions
mathDesc.addVariable(new Function(FRAPStudy.SPECIES_NAME_PREFIX_COMBINED, new Expression(species[FREE_SPECIES_INDEX].getCommonName() + "+" + species[COMPLEX_SPECIES_INDEX].getCommonName() + "+" + species[IMMOBILE_SPECIES_INDEX].getCommonName()), null));
simContext.setMathDescription(mathDesc);
SimulationVersion simVersion = new SimulationVersion(simKey, "sim1", owner, new GroupAccessNone(), new KeyValue("0"), new BigDecimal(0), new Date(), VersionFlag.Current, "", null);
Simulation newSimulation = new Simulation(simVersion, mathDesc);
simContext.addSimulation(newSimulation);
newSimulation.getSolverTaskDescription().setTimeBounds(timeBounds);
newSimulation.getMeshSpecification().setSamplingSize(cellROI_2D.getISize());
// newSimulation.getSolverTaskDescription().setTimeStep(timeStep); // Sundials doesn't need time step
newSimulation.getSolverTaskDescription().setSolverDescription(SolverDescription.SundialsPDE);
// use exp time step as output time spec
newSimulation.getSolverTaskDescription().setOutputTimeSpec(new UniformOutputTimeSpec(timeStepVal));
return bioModel;
}
use of cbit.vcell.solver.TimeBounds in project vcell by virtualcell.
the class DefaultODESolver method getProgress.
/**
* Insert the method's description here.
* Creation date: (6/28/01 2:37:27 PM)
* @return double
*/
public double getProgress() {
Simulation sim = simTask.getSimulation();
double currTime = getCurrentTime();
TimeBounds timeBounds = sim.getSolverTaskDescription().getTimeBounds();
double startTime = timeBounds.getStartingTime();
double endTime = timeBounds.getEndingTime();
if ((endTime - startTime) == 0.0) {
throw new RuntimeException("DefaultODESolver.getProgress(), endTime==startTime");
} else {
return currTime / (endTime - startTime);
}
}
use of cbit.vcell.solver.TimeBounds in project vcell by virtualcell.
the class SundialsSolver method getApplicationMessage.
/**
* Insert the method's description here.
* Creation date: (6/27/01 3:25:11 PM)
* @return cbit.vcell.solvers.ApplicationMessage
* @param message java.lang.String
*/
protected ApplicationMessage getApplicationMessage(String message) {
//
if (message.startsWith(PROGRESS_PREFIX)) {
String progressString = message.substring(message.lastIndexOf(SEPARATOR) + 1, message.indexOf("%"));
double progress = Double.parseDouble(progressString) / 100.0;
TimeBounds timeBounds = simTask.getSimulation().getSolverTaskDescription().getTimeBounds();
double startTime = timeBounds.getStartingTime();
double endTime = timeBounds.getEndingTime();
setCurrentTime(startTime + (endTime - startTime) * progress);
return new ApplicationMessage(ApplicationMessage.PROGRESS_MESSAGE, progress, -1, null, message);
} else if (message.startsWith(DATA_PREFIX)) {
double timepoint = Double.parseDouble(message.substring(message.lastIndexOf(SEPARATOR) + 1));
setCurrentTime(timepoint);
return new ApplicationMessage(ApplicationMessage.DATA_MESSAGE, getProgress(), timepoint, null, message);
} else {
throw new RuntimeException("unrecognized message");
}
}
use of cbit.vcell.solver.TimeBounds in project vcell by virtualcell.
the class OdeFileWriter method write.
/**
* Insert the method's description here.
* Creation date: (3/8/00 10:31:52 PM)
*/
public void write(String[] parameterNames) throws Exception {
createStateVariables();
createSymbolTable();
Simulation simulation = simTask.getSimulation();
if (simulation.getSolverTaskDescription().getUseSymbolicJacobian()) {
throw new RuntimeException("symbolic jacobian option not yet supported in interpreted Stiff solver");
}
writeJMSParamters();
SolverTaskDescription solverTaskDescription = simulation.getSolverTaskDescription();
TimeBounds timeBounds = solverTaskDescription.getTimeBounds();
ErrorTolerance errorTolerance = solverTaskDescription.getErrorTolerance();
printWriter.println("SOLVER " + getSolverName());
printWriter.println("STARTING_TIME " + timeBounds.getStartingTime());
printWriter.println("ENDING_TIME " + timeBounds.getEndingTime());
printWriter.println("RELATIVE_TOLERANCE " + errorTolerance.getRelativeErrorTolerance());
printWriter.println("ABSOLUTE_TOLERANCE " + errorTolerance.getAbsoluteErrorTolerance());
printWriter.println("MAX_TIME_STEP " + simulation.getSolverTaskDescription().getTimeStep().getMaximumTimeStep());
OutputTimeSpec ots = simulation.getSolverTaskDescription().getOutputTimeSpec();
if (ots.isDefault()) {
printWriter.println("KEEP_EVERY " + ((DefaultOutputTimeSpec) ots).getKeepEvery());
} else if (ots.isUniform()) {
printWriter.println("OUTPUT_TIME_STEP " + ((UniformOutputTimeSpec) ots).getOutputTimeStep());
} else if (ots.isExplicit()) {
printWriter.println("OUTPUT_TIMES " + ((ExplicitOutputTimeSpec) ots).getNumTimePoints());
printWriter.println(((ExplicitOutputTimeSpec) ots).toSpaceSeperatedMultiLinesOfString());
}
if (parameterNames != null && parameterNames.length != 0) {
printWriter.println("NUM_PARAMETERS " + parameterNames.length);
for (int i = 0; i < parameterNames.length; i++) {
printWriter.println(parameterNames[i]);
}
}
HashMap<Discontinuity, String> discontinuityNameMap = new HashMap<Discontinuity, String>();
String eventString = null;
if (simulation.getMathDescription().hasEvents()) {
eventString = writeEvents(discontinuityNameMap);
}
String equationString = writeEquations(discontinuityNameMap);
if (discontinuityNameMap.size() > 0) {
printWriter.println("DISCONTINUITIES " + discontinuityNameMap.size());
for (Discontinuity od : discontinuityNameMap.keySet()) {
printWriter.println(discontinuityNameMap.get(od) + " " + od.getDiscontinuityExp().flatten().infix() + "; " + od.getRootFindingExp().flatten().infix() + ";");
}
}
if (eventString != null) {
printWriter.print(eventString);
}
printWriter.println("NUM_EQUATIONS " + getStateVariableCount());
printWriter.println(equationString);
}
Aggregations