use of org.vcell.sedml.RelativeFileModelResolver in project vcell by virtualcell.
the class XmlHelper method sedmlToBioModel.
public static VCDocument sedmlToBioModel(VCLogger transLogger, ExternalDocInfo externalDocInfo, SedML sedml, AbstractTask selectedTask) throws Exception {
if (sedml.getModels().isEmpty()) {
return null;
}
VCDocument doc = null;
try {
// extract the path only from the sedml file
String fullPath = FileUtils.getFullPath(externalDocInfo.getFile().getAbsolutePath());
// Namespace namespace = sedml.getNamespace();
// iterate through all the elements and show them at the console
List<org.jlibsedml.Model> mmm = sedml.getModels();
for (Model mm : mmm) {
System.out.println(mm.toString());
}
List<org.jlibsedml.Simulation> sss = sedml.getSimulations();
for (org.jlibsedml.Simulation ss : sss) {
System.out.println(ss.toString());
}
List<AbstractTask> ttt = sedml.getTasks();
for (AbstractTask tt : ttt) {
System.out.println(tt.toString());
}
List<DataGenerator> ddd = sedml.getDataGenerators();
for (DataGenerator dd : ddd) {
System.out.println(dd.toString());
}
List<Output> ooo = sedml.getOutputs();
for (Output oo : ooo) {
System.out.println(oo.toString());
}
KisaoTerm sedmlKisao = null;
// this will become the vCell simulation
org.jlibsedml.Simulation sedmlSimulation = null;
// the "original" model referred to by the task
org.jlibsedml.Model sedmlOriginalModel = null;
String sedmlOriginalModelName = null;
if (selectedTask == null) {
// no task, just pick the Model and find its sbml file
sedmlOriginalModelName = SEDMLUtil.getName(mmm.get(0));
} else {
if (selectedTask instanceof Task) {
sedmlOriginalModel = sedml.getModelWithId(selectedTask.getModelReference());
sedmlSimulation = sedml.getSimulation(selectedTask.getSimulationReference());
} else if (selectedTask instanceof RepeatedTask) {
RepeatedTask rt = (RepeatedTask) selectedTask;
assert (rt.getSubTasks().size() == 1);
// first (and only) subtask
SubTask st = rt.getSubTasks().entrySet().iterator().next().getValue();
String taskId = st.getTaskId();
AbstractTask t = sedml.getTaskWithId(taskId);
// get model and simulation from subtask
sedmlOriginalModel = sedml.getModelWithId(t.getModelReference());
sedmlSimulation = sedml.getSimulation(t.getSimulationReference());
} else {
throw new RuntimeException("Unexpected task " + selectedTask);
}
sedmlOriginalModelName = sedmlOriginalModel.getId();
sedmlKisao = KisaoOntology.getInstance().getTermById(sedmlSimulation.getAlgorithm().getKisaoID());
}
// UniformTimeCourse [initialTime=0.0, numberOfPoints=1000, outputEndTime=1.0, outputStartTime=0.0,
// Algorithm [kisaoID=KISAO:0000019], getId()=SimSlow]
// identify the vCell solvers that would match best the sedml solver kisao id
List<SolverDescription> solverDescriptions = new ArrayList<>();
for (SolverDescription sd : SolverDescription.values()) {
KisaoTerm solverKisaoTerm = KisaoOntology.getInstance().getTermById(sd.getKisao());
if (solverKisaoTerm == null) {
break;
}
boolean isExactlySame = solverKisaoTerm.equals(sedmlKisao);
if (isExactlySame && !solverKisaoTerm.isObsolete()) {
// we make a list with all the solvers that match the kisao
solverDescriptions.add(sd);
}
}
// from the list of vcell solvers that match the sedml kisao we select the ones that have a matching time step
SolverDescription solverDescription = null;
for (SolverDescription sd : solverDescriptions) {
if (true) {
solverDescription = sd;
break;
}
}
// find out everything else we need about the application we're going to use,
// some of the info will be needed when we parse the sbml file
boolean bSpatial = false;
Application appType = Application.NETWORK_DETERMINISTIC;
Set<SolverDescription.SolverFeature> sfList = solverDescription.getSupportedFeatures();
for (SolverDescription.SolverFeature sf : sfList) {
switch(sf) {
case Feature_Rulebased:
appType = Application.RULE_BASED_STOCHASTIC;
break;
case Feature_Stochastic:
appType = Application.NETWORK_STOCHASTIC;
break;
case Feature_Deterministic:
appType = Application.NETWORK_DETERMINISTIC;
break;
case Feature_Spatial:
bSpatial = true;
break;
default:
break;
}
}
// -------------------------------------------------------------------------------------------
// extract bioModel name from sedx (or sedml) file
String bioModelName = FileUtils.getBaseName(externalDocInfo.getFile().getAbsolutePath());
// if we have repeated task, we ignore them, we just use the normal resolvers for archive and changes
// once the application and simulation are built, we iterate through the repeated tasks and
// add math overrides to the simulation for each repeated task
ArchiveComponents ac = null;
if (externalDocInfo.getFile().getPath().toLowerCase().endsWith("sedx") || externalDocInfo.getFile().getPath().toLowerCase().endsWith("omex")) {
ac = Libsedml.readSEDMLArchive(new FileInputStream(externalDocInfo.getFile().getPath()));
}
ModelResolver resolver = new ModelResolver(sedml);
if (ac != null) {
resolver.add(new ArchiveModelResolver(ac));
}
resolver.add(new FileModelResolver());
resolver.add(new RelativeFileModelResolver(fullPath));
String newMdl = resolver.getModelString(sedmlOriginalModel);
// sbmlSource with all the changes applied
XMLSource sbmlSource = new XMLSource(newMdl);
doc = XmlHelper.importSBML(transLogger, sbmlSource, bSpatial);
BioModel bioModel = (BioModel) doc;
bioModel.setName(bioModelName);
// we already have an application loaded from the sbml file, with initial conditions and stuff
// which may be not be suitable because the sedml kisao may need a different app type
// so we do a "copy as" to the right type and then delete the original we loaded from the sbml file
// the new application we're making from the old one
SimulationContext newSimulationContext = null;
if (bioModel.getSimulationContexts().length == 1) {
SimulationContext oldSimulationContext = bioModel.getSimulationContext(0);
newSimulationContext = SimulationContext.copySimulationContext(oldSimulationContext, sedmlOriginalModelName, bSpatial, appType);
bioModel.removeSimulationContext(oldSimulationContext);
bioModel.addSimulationContext(newSimulationContext);
} else {
// length == 0
newSimulationContext = bioModel.addNewSimulationContext(sedmlOriginalModelName, appType);
}
// making the new vCell simulation based on the sedml simulation
newSimulationContext.refreshDependencies();
MathMappingCallback callback = new MathMappingCallbackTaskAdapter(null);
newSimulationContext.refreshMathDescription(callback, NetworkGenerationRequirements.ComputeFullStandardTimeout);
Simulation newSimulation = new Simulation(newSimulationContext.getMathDescription());
newSimulation.setName(SEDMLUtil.getName(sedmlSimulation));
// TODO: make sure that everything has proper names
// we check the repeated tasks, if any, and add to the list of math overrides
// if(selectedTask instanceof RepeatedTask) {
// for(Change change : ((RepeatedTask) selectedTask).getChanges()) {
// if(!(change instanceof SetValue)) {
// throw new RuntimeException("Only 'SetValue' changes are supported for repeated tasks.");
// }
// SetValue setValue = (SetValue)change;
// // TODO: extract target from XPath
// // ......
// //
// String target = "s0"; // for now we just use a hardcoded thing
// ConstantArraySpec cas;
// Range range = ((RepeatedTask) selectedTask).getRange(setValue.getRangeReference());
// if(range instanceof UniformRange) {
// cas = ConstantArraySpec.createIntervalSpec(target, ((UniformRange) range).getStart(), ((UniformRange) range).getEnd(),
// range.getNumElements(), ((UniformRange) range).getType() == UniformRange.UniformType.LOG ? true : false);
// } else if(range instanceof VectorRange) {
// // List<String> constants = new ArrayList<> ();
// // for(int i=0; i<range.getNumElements(); i++) {
// // constants.add(new Constant(i+"", new Expression(range.getElementAt(i))));
// // }
// // cas = ConstantArraySpec.createListSpec(target, constants);
//
// } else {
// throw new RuntimeException("Only 'Uniform Range' and 'Vector Range' are supported at this time.");
// }
//
// }
// }
// we identify the type of sedml simulation (uniform time course, etc)
// and set the vCell simulation parameters accordingly
SolverTaskDescription simTaskDesc = newSimulation.getSolverTaskDescription();
TimeBounds timeBounds = new TimeBounds();
TimeStep timeStep = new TimeStep();
double outputTimeStep = 0.1;
if (sedmlSimulation instanceof UniformTimeCourse) {
// we translate initial time to zero, we provide output for the duration of the simulation
// because we can't select just an interval the way the SEDML simulation can
double initialTime = ((UniformTimeCourse) sedmlSimulation).getInitialTime();
double outputStartTime = ((UniformTimeCourse) sedmlSimulation).getOutputStartTime();
double outputEndTime = ((UniformTimeCourse) sedmlSimulation).getOutputEndTime();
double outputNumberOfPoints = ((UniformTimeCourse) sedmlSimulation).getNumberOfPoints();
outputTimeStep = (outputEndTime - outputStartTime) / outputNumberOfPoints;
timeBounds = new TimeBounds(0, outputEndTime - initialTime);
} else if (sedmlSimulation instanceof OneStep) {
// for anything other than UniformTimeCourse we just ignore
} else if (sedmlSimulation instanceof SteadyState) {
} else {
}
OutputTimeSpec outputTimeSpec = new UniformOutputTimeSpec(outputTimeStep);
simTaskDesc.setTimeBounds(timeBounds);
simTaskDesc.setTimeStep(timeStep);
simTaskDesc.setOutputTimeSpec(outputTimeSpec);
newSimulation.setSolverTaskDescription(simTaskDesc);
bioModel.addSimulation(newSimulation);
newSimulation.refreshDependencies();
} catch (Exception e) {
e.printStackTrace();
throw new RuntimeException("Unable to initialize bioModel for the given selection.");
}
return doc;
}
use of org.vcell.sedml.RelativeFileModelResolver in project vcell by virtualcell.
the class XmlHelper method sedmlToBioModel.
public static List<VCDocument> sedmlToBioModel(VCLogger transLogger, ExternalDocInfo externalDocInfo, SedML sedml, List<AbstractTask> tasks, String sedmlFileLocation, boolean exactMatchOnly) throws Exception {
if (sedml.getModels().isEmpty()) {
throw new Exception("No models found in SED-ML document");
}
try {
// iterate through all the elements and show them at the console
List<org.jlibsedml.Model> mmm = sedml.getModels();
for (Model mm : mmm) {
System.out.println(mm.toString());
}
List<org.jlibsedml.Simulation> sss = sedml.getSimulations();
for (org.jlibsedml.Simulation ss : sss) {
System.out.println(ss.toString());
}
List<AbstractTask> ttt = sedml.getTasks();
if (ttt.isEmpty()) {
throw new Exception("No tasks found in SED-ML document");
}
for (AbstractTask tt : ttt) {
System.out.println(tt.toString());
}
List<DataGenerator> ddd = sedml.getDataGenerators();
for (DataGenerator dd : ddd) {
System.out.println(dd.toString());
}
List<Output> ooo = sedml.getOutputs();
for (Output oo : ooo) {
System.out.println(oo.toString());
}
if (ooo.isEmpty()) {
System.err.println("List of outputs cannot be empty!");
}
if (tasks == null || tasks.isEmpty()) {
// no task selection, we'll import all that we find in the SED-ML
tasks = sedml.getTasks();
}
// We need to make a separate BioModel for each SED-ML model
// We will parse all tasks and create Simulations for each in the BioModel(s) corresponding to the model referenced by the tasks
List<VCDocument> docs = new ArrayList<VCDocument>();
// extract bioModel name from sedx (or sedml) file
String bioModelBaseName = FileUtils.getBaseName(externalDocInfo.getFile().getAbsolutePath());
String kisaoID = null;
// this will become the vCell simulation
org.jlibsedml.Simulation sedmlSimulation = null;
// the "original" model referred to by the task
org.jlibsedml.Model sedmlOriginalModel = null;
// this will be used in the BioModel name
String sedmlOriginalModelName = null;
// can be sbml or vcml
String sedmlOriginalModelLanguage = null;
ArchiveComponents ac = null;
if (externalDocInfo.getFile().getPath().toLowerCase().endsWith("sedx") || externalDocInfo.getFile().getPath().toLowerCase().endsWith("omex")) {
ac = Libsedml.readSEDMLArchive(new FileInputStream(externalDocInfo.getFile().getPath()));
}
ModelResolver resolver = new ModelResolver(sedml);
if (ac != null) {
resolver.add(new ArchiveModelResolver(ac));
}
resolver.add(new FileModelResolver());
if (sedmlFileLocation != null) {
File sedmlFile = new File(sedmlFileLocation);
String sedmlRelativePrefix = sedmlFile.getParent() + File.separator;
if (sedmlRelativePrefix != null) {
resolver.add(new RelativeFileModelResolver(sedmlRelativePrefix));
}
}
for (AbstractTask selectedTask : tasks) {
if (selectedTask instanceof Task) {
sedmlOriginalModel = sedml.getModelWithId(selectedTask.getModelReference());
sedmlSimulation = sedml.getSimulation(selectedTask.getSimulationReference());
} else if (selectedTask instanceof RepeatedTask) {
System.err.println("RepeatedTask not supported yet, task " + SEDMLUtil.getName(selectedTask) + " is being skipped");
continue;
// TODO the below is unfinished code
// RepeatedTask rt = (RepeatedTask)selectedTask;
// assert(rt.getSubTasks().size() == 1);
// SubTask st = rt.getSubTasks().entrySet().iterator().next().getValue(); // first (and only) subtask
// String taskId = st.getTaskId();
// AbstractTask t = sedml.getTaskWithId(taskId);
// sedmlOriginalModel = sedml.getModelWithId(t.getModelReference()); // get model and simulation from subtask
// sedmlSimulation = sedml.getSimulation(t.getSimulationReference());
} else {
throw new RuntimeException("Unexpected task " + selectedTask);
}
sedmlOriginalModelName = sedmlOriginalModel.getId();
sedmlOriginalModelLanguage = sedmlOriginalModel.getLanguage();
// at this point we assume that the sedml simulation, algorithm and kisaoID are all valid
Algorithm algorithm = sedmlSimulation.getAlgorithm();
kisaoID = algorithm.getKisaoID();
// identify the vCell solvers that would match best the sedml solver kisao id
// try to find a match in the ontology tree
SolverDescription solverDescription = SolverUtilities.matchSolverWithKisaoId(kisaoID, exactMatchOnly);
if (solverDescription != null) {
System.out.println("Task (id='" + selectedTask.getId() + "') is compatible, solver match found in ontology: '" + kisaoID + "' matched to " + solverDescription);
} else {
// give it a try anyway with our deterministic default solver
solverDescription = SolverDescription.CombinedSundials;
System.err.println("Task (id='" + selectedTask.getId() + ")' is not compatible, no equivalent solver found in ontology for requested algorithm '" + kisaoID + "'; trying with deterministic default solver " + solverDescription);
}
// find out everything else we need about the application we're going to use,
// some of the info will be needed when we parse the sbml file
boolean bSpatial = false;
Application appType = Application.NETWORK_DETERMINISTIC;
Set<SolverDescription.SolverFeature> sfList = solverDescription.getSupportedFeatures();
for (SolverDescription.SolverFeature sf : sfList) {
switch(sf) {
case Feature_Rulebased:
appType = Application.RULE_BASED_STOCHASTIC;
break;
case Feature_Stochastic:
appType = Application.NETWORK_STOCHASTIC;
break;
case Feature_Deterministic:
appType = Application.NETWORK_DETERMINISTIC;
break;
case Feature_Spatial:
bSpatial = true;
break;
default:
break;
}
}
// we make a biomodel for each task; if there are many simulations, probably
// only one will match the selected task id, the others are parasites and must not be run
BioModel bioModel = null;
boolean justMade = false;
String newMdl = resolver.getModelString(sedmlOriginalModel);
String bioModelName = bioModelBaseName + "_" + sedml.getFileName() + "_" + sedmlOriginalModelName;
// get it if we made it already
for (VCDocument existingDoc : docs) {
if (!docs.isEmpty()) {
if (existingDoc.getName().equals(bioModelName)) {
bioModel = (BioModel) existingDoc;
break;
}
}
}
// make it if we didn't and mark it as fresh
if (bioModel == null) {
if (sedmlOriginalModelLanguage.contentEquals(SUPPORTED_LANGUAGE.VCELL_GENERIC.getURN())) {
// vcml
XMLSource vcmlSource = new XMLSource(newMdl);
bioModel = (BioModel) XmlHelper.XMLToBioModel(vcmlSource);
bioModel.setName(bioModelName);
docs.add(bioModel);
justMade = true;
try {
bioModel.getVCMetaData().createBioPaxObjects(bioModel);
} catch (Exception e) {
e.printStackTrace();
}
} else {
// we assume it's sbml, if it's neither import will fail
// sbmlSource with all the changes applied
XMLSource sbmlSource = new XMLSource(newMdl);
bioModel = (BioModel) XmlHelper.importSBML(transLogger, sbmlSource, bSpatial);
bioModel.setName(bioModelName);
docs.add(bioModel);
justMade = true;
}
}
if (sedmlOriginalModelLanguage.contentEquals(SUPPORTED_LANGUAGE.VCELL_GENERIC.getURN())) {
// we basically ignore the sedml simulation altogether
for (Simulation sim : bioModel.getSimulations()) {
if (sim.getName().equals(selectedTask.getName())) {
System.out.println(" --- selected task - name: " + selectedTask.getName() + ", id: " + selectedTask.getId());
sim.setImportedTaskID(selectedTask.getId());
}
}
continue;
}
// even if we just created the biomodel from the sbml file we have at least one application with initial conditions and stuff
// see if there is a suitable application type for the sedml kisao
// if not, we add one by doing a "copy as" to the right type
SimulationContext[] existingSimulationContexts = bioModel.getSimulationContexts();
SimulationContext matchingSimulationContext = null;
for (SimulationContext simContext : existingSimulationContexts) {
if (simContext.getApplicationType().equals(appType) && ((simContext.getGeometry().getDimension() > 0) == bSpatial)) {
matchingSimulationContext = simContext;
break;
}
}
if (matchingSimulationContext == null) {
if (justMade) {
matchingSimulationContext = SimulationContext.copySimulationContext(existingSimulationContexts[0], sedmlOriginalModelName, bSpatial, appType);
bioModel.removeSimulationContext(existingSimulationContexts[0]);
} else {
matchingSimulationContext = SimulationContext.copySimulationContext(existingSimulationContexts[0], sedmlOriginalModelName + "_" + existingSimulationContexts.length, bSpatial, appType);
}
bioModel.addSimulationContext(matchingSimulationContext);
}
// making the new vCell simulation based on the sedml simulation
matchingSimulationContext.refreshDependencies();
MathMappingCallback callback = new MathMappingCallbackTaskAdapter(null);
matchingSimulationContext.refreshMathDescription(callback, NetworkGenerationRequirements.ComputeFullStandardTimeout);
Simulation newSimulation = new Simulation(matchingSimulationContext.getMathDescription());
newSimulation.setSimulationOwner(matchingSimulationContext);
if (selectedTask instanceof Task) {
String newSimName = selectedTask.getId();
if (SEDMLUtil.getName(selectedTask) != null) {
newSimName += "_" + SEDMLUtil.getName(selectedTask);
}
newSimulation.setName(newSimName);
newSimulation.setImportedTaskID(selectedTask.getId());
} else {
newSimulation.setName(SEDMLUtil.getName(sedmlSimulation) + "_" + SEDMLUtil.getName(selectedTask));
}
// we identify the type of sedml simulation (uniform time course, etc)
// and set the vCell simulation parameters accordingly
SolverTaskDescription simTaskDesc = newSimulation.getSolverTaskDescription();
if (solverDescription != null) {
simTaskDesc.setSolverDescription(solverDescription);
}
TimeBounds timeBounds = new TimeBounds();
TimeStep timeStep = new TimeStep();
double outputTimeStep = 0.1;
int outputNumberOfPoints = 1;
if (sedmlSimulation instanceof UniformTimeCourse) {
// we translate initial time to zero, we provide output for the duration of the simulation
// because we can't select just an interval the way the SEDML simulation can
double initialTime = ((UniformTimeCourse) sedmlSimulation).getInitialTime();
double outputStartTime = ((UniformTimeCourse) sedmlSimulation).getOutputStartTime();
double outputEndTime = ((UniformTimeCourse) sedmlSimulation).getOutputEndTime();
outputNumberOfPoints = ((UniformTimeCourse) sedmlSimulation).getNumberOfPoints();
outputTimeStep = (outputEndTime - outputStartTime) / outputNumberOfPoints;
timeBounds = new TimeBounds(0, outputEndTime - initialTime);
ErrorTolerance errorTolerance = new ErrorTolerance();
// we look for explicit algorithm parameters
List<AlgorithmParameter> sedmlAlgorithmParameters = algorithm.getListOfAlgorithmParameters();
for (AlgorithmParameter sedmlAlgorithmParameter : sedmlAlgorithmParameters) {
String apKisaoID = sedmlAlgorithmParameter.getKisaoID();
String apValue = sedmlAlgorithmParameter.getValue();
if (apKisaoID == null || apKisaoID.isEmpty()) {
System.err.println("Undefined KisaoID algorithm parameter for algorithm '" + kisaoID + "'");
}
// TODO: use the proper ontology for the algorithm parameters kisao id
if (apKisaoID.contentEquals(ErrorTolerance.ErrorToleranceDescription.Absolute.getKisao())) {
double value = Double.parseDouble(apValue);
errorTolerance.setAbsoluteErrorTolerance(value);
} else if (apKisaoID.contentEquals(ErrorTolerance.ErrorToleranceDescription.Relative.getKisao())) {
double value = Double.parseDouble(apValue);
errorTolerance.setRelativeErrorTolerance(value);
} else if (apKisaoID.contentEquals(TimeStep.TimeStepDescription.Default.getKisao())) {
double value = Double.parseDouble(apValue);
timeStep.setDefaultTimeStep(value);
} else if (apKisaoID.contentEquals(TimeStep.TimeStepDescription.Maximum.getKisao())) {
double value = Double.parseDouble(apValue);
timeStep.setMaximumTimeStep(value);
} else if (apKisaoID.contentEquals(TimeStep.TimeStepDescription.Minimum.getKisao())) {
double value = Double.parseDouble(apValue);
timeStep.setMinimumTimeStep(value);
} else if (apKisaoID.contentEquals(AlgorithmParameterDescription.Seed.getKisao())) {
// custom seed
if (simTaskDesc.getSimulation().getMathDescription().isNonSpatialStoch()) {
NonspatialStochSimOptions nssso = simTaskDesc.getStochOpt();
int value = Integer.parseInt(apValue);
nssso.setCustomSeed(value);
} else {
System.err.println("Algorithm parameter '" + AlgorithmParameterDescription.Seed.getDescription() + "' is only supported for nonspatial stochastic simulations");
}
// some arguments used only for non-spatial hybrid solvers
} else if (apKisaoID.contentEquals(AlgorithmParameterDescription.Epsilon.getKisao())) {
NonspatialStochHybridOptions nssho = simTaskDesc.getStochHybridOpt();
nssho.setEpsilon(Double.parseDouble(apValue));
} else if (apKisaoID.contentEquals(AlgorithmParameterDescription.Lambda.getKisao())) {
NonspatialStochHybridOptions nssho = simTaskDesc.getStochHybridOpt();
nssho.setLambda(Double.parseDouble(apValue));
} else if (apKisaoID.contentEquals(AlgorithmParameterDescription.MSRTolerance.getKisao())) {
NonspatialStochHybridOptions nssho = simTaskDesc.getStochHybridOpt();
nssho.setMSRTolerance(Double.parseDouble(apValue));
} else if (apKisaoID.contentEquals(AlgorithmParameterDescription.SDETolerance.getKisao())) {
NonspatialStochHybridOptions nssho = simTaskDesc.getStochHybridOpt();
nssho.setSDETolerance(Double.parseDouble(apValue));
} else {
System.err.println("Algorithm parameter with kisao id '" + apKisaoID + "' not supported at this time, skipping.");
}
}
simTaskDesc.setErrorTolerance(errorTolerance);
} else if (sedmlSimulation instanceof OneStep) {
// for anything other than UniformTimeCourse we just ignore
System.err.println("OneStep Simulation not supported");
continue;
} else if (sedmlSimulation instanceof SteadyState) {
System.err.println("SteadyState Simulation not supported");
continue;
}
OutputTimeSpec outputTimeSpec = new UniformOutputTimeSpec(outputTimeStep);
simTaskDesc.setTimeBounds(timeBounds);
simTaskDesc.setTimeStep(timeStep);
if (simTaskDesc.getSolverDescription().supports(outputTimeSpec)) {
simTaskDesc.setOutputTimeSpec(outputTimeSpec);
} else {
simTaskDesc.setOutputTimeSpec(new DefaultOutputTimeSpec(1, Integer.max(DefaultOutputTimeSpec.DEFAULT_KEEP_AT_MOST, outputNumberOfPoints)));
}
newSimulation.setSolverTaskDescription(simTaskDesc);
newSimulation.setDescription(SEDMLUtil.getName(selectedTask));
bioModel.addSimulation(newSimulation);
newSimulation.refreshDependencies();
}
return docs;
} catch (Exception e) {
e.printStackTrace();
throw new RuntimeException("Unable to initialize bioModel for the given selection\n" + e.getMessage());
}
}
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