Ejemplo n.º 1
0
    static void Main()
    {
        Debug.Assert(CRootContainer.getRoot() != null);
        // create a new datamodel
        CDataModel dataModel = CRootContainer.addDatamodel();

        Debug.Assert(CRootContainer.getDatamodelList().size() == 1);
        // the only argument to the main routine should be the name of an SBML file
        try
        {
            // load the model
            dataModel.importSBMLFromString(MODEL_STRING);
        }
        catch
        {
            System.Console.Error.WriteLine("Error while importing the model from the given String.");
            System.Environment.Exit(1);
        }
        CModel model = dataModel.getModel();

        Debug.Assert(model != null);
        // create a report with the correct filename and all the species against
        // time.
        CReportDefinitionVector reports = dataModel.getReportDefinitionList();
        // create a new report definition object
        CReportDefinition report = reports.createReportDefinition("Report", "Output for timecourse");

        // set the task type for the report definition to timecourse
        report.setTaskType(CTaskEnum.Task_timeCourse);
        // we don't want a table
        report.setIsTable(false);
        // the entries in the output should be seperated by a ", "
        report.setSeparator(new CCopasiReportSeparator(", "));

        // we need a handle to the header and the body
        // the header will display the ids of the metabolites and "time" for
        // the first column
        // the body will contain the actual timecourse data
        ReportItemVector header = report.getHeaderAddr();
        ReportItemVector body   = report.getBodyAddr();

        body.Add(new CRegisteredCommonName(new CCommonName(dataModel.getModel().getCN().getString() + ",Reference=Time").getString()));
        body.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
        header.Add(new CRegisteredCommonName(new CDataString("time").getCN().getString()));
        header.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));

        uint i, iMax = (uint)model.getMetabolites().size();

        for (i = 0; i < iMax; ++i)
        {
            CMetab metab = model.getMetabolite(i);
            Debug.Assert(metab != null);
            // we don't want output for FIXED metabolites right now
            if (metab.getStatus() != CModelEntity.Status_FIXED)
            {
                // we want the concentration oin the output
                // alternatively, we could use "Reference=Amount" to get the
                // particle number
                body.Add(new CRegisteredCommonName(metab.getObject(new CCommonName("Reference=Concentration")).getCN().getString()));
                // add the corresponding id to the header
                header.Add(new CRegisteredCommonName(new CDataString(metab.getSBMLId()).getCN().getString()));

                if (i != iMax - 1)
                {
                    // after each entry, we need a seperator
                    body.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));

                    // and a seperator
                    header.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
                }
            }
        }

        // get the trajectory task object
        CTrajectoryTask trajectoryTask = (CTrajectoryTask)dataModel.getTask("Time-Course");

        // run a stochastic time course
        trajectoryTask.setMethodType(CTaskEnum.Method_stochastic);

        // pass a pointer of the model to the problem
        trajectoryTask.getProblem().setModel(dataModel.getModel());

        // we don't want the trajectory task to run by itself, but we want to
        // run it from a scan, so we deactivate the standalone trajectory task
        trajectoryTask.setScheduled(false);

        // get the problem for the task to set some parameters
        CTrajectoryProblem problem = (CTrajectoryProblem)trajectoryTask.getProblem();

        // simulate 100 steps
        problem.setStepNumber(100);
        // start at time 0
        dataModel.getModel().setInitialTime(0.0);
        // simulate a duration of 10 time units
        problem.setDuration(10);
        // tell the problem to actually generate time series data
        problem.setTimeSeriesRequested(true);

        // now we set up the scan
        CScanTask scanTask = (CScanTask)dataModel.getTask("Scan");

        // get the problem
        CScanProblem scanProblem = (CScanProblem)scanTask.getProblem();

        Debug.Assert(scanProblem != null);

        // set the model for the problem
        scanProblem.setModel(dataModel.getModel());

        // activate the task so that is is run
        // if the model is saved and passed to CopasiSE
        scanTask.setScheduled(true);

        // set the report for the task
        scanTask.getReport().setReportDefinition(report);

        // set the output file for the report
        scanTask.getReport().setTarget("example4.txt");
        // don't append to an existing file, but overwrite
        scanTask.getReport().setAppend(false);

        // tell the scan that we want to make a scan over a trajectory task
        scanProblem.setSubtask(CTaskEnum.Task_timeCourse);

        // we just want to run the timecourse task a number of times, so we
        // create a repeat item with 100 repeats
        scanProblem.addScanItem(CScanProblem.SCAN_REPEAT, 100);

        // we want the output from the trajectory task
        scanProblem.setOutputInSubtask(true);

        // we don't want to set the initial conditions of the model to the end
        // state of the last run
        scanProblem.setContinueFromCurrentState(false);

        try
        {
            // now we run the actual trajectory
            scanTask.processWithOutputFlags(true, (int)CCopasiTask.ONLY_TIME_SERIES);
        }
        catch
        {
            System.Console.Error.WriteLine("Error. Running the scan failed.");
            String lastErrors = scanTask.getProcessError();
            // check if there are additional error messages
            if (!string.IsNullOrEmpty(lastErrors))
            {
                // print the messages in chronological order
                System.Console.Error.WriteLine(lastErrors);
            }

            System.Environment.Exit(1);
        }
    }
Ejemplo n.º 2
0
    static void Main(string[] args)
    {
        Debug.Assert(CRootContainer.getRoot() != null);
        // create a new datamodel
        CDataModel dataModel = CRootContainer.addDatamodel();

        Debug.Assert(CRootContainer.getDatamodelList().size() == 1);
        // the only argument to the main routine should be the name of an SBML file
        if (args.Length == 1)
        {
            string filename = args[0];
            try
            {
                // load the model
                dataModel.importSBML(filename);
            }
            catch
            {
                System.Console.Error.WriteLine("Error while importing the model from file named \"" + filename + "\".");
                System.Environment.Exit(1);
            }
            CModel model = dataModel.getModel();
            Debug.Assert(model != null);
            // create a report with the correct filename and all the species against
            // time.
            CReportDefinitionVector reports = dataModel.getReportDefinitionList();
            // create a new report definition object
            CReportDefinition report = reports.createReportDefinition("Report", "Output for timecourse");
            // set the task type for the report definition to timecourse
            report.setTaskType(CTaskEnum.Task_timeCourse);
            // we don't want a table
            report.setIsTable(false);
            // the entries in the output should be seperated by a ", "
            report.setSeparator(new CCopasiReportSeparator(", "));

            // we need a handle to the header and the body
            // the header will display the ids of the metabolites and "time" for
            // the first column
            // the body will contain the actual timecourse data
            ReportItemVector header = report.getHeaderAddr();
            ReportItemVector body   = report.getBodyAddr();

            body.Add(new CRegisteredCommonName(model.getObject(new CCommonName("Reference=Time")).getCN().getString()));
            body.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
            header.Add(new CRegisteredCommonName(new CDataString("time").getCN().getString()));
            header.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));

            uint i, iMax = (uint)model.getMetabolites().size();
            for (i = 0; i < iMax; ++i)
            {
                CMetab metab = model.getMetabolite(i);
                Debug.Assert(metab != null);
                // we don't want output for FIXED metabolites right now
                if (metab.getStatus() != CModelEntity.Status_FIXED)
                {
                    // we want the concentration oin the output
                    // alternatively, we could use "Reference=Amount" to get the
                    // particle number
                    body.Add(new CRegisteredCommonName(metab.getObject(new CCommonName("Reference=Concentration")).getCN().getString()));
                    // add the corresponding id to the header
                    header.Add(new CRegisteredCommonName(new CDataString(metab.getSBMLId()).getCN().getString()));
                    // after each entry, we need a seperator
                    if (i != iMax - 1)
                    {
                        body.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
                        header.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
                    }
                }
            }


            // get the trajectory task object
            CTrajectoryTask trajectoryTask = (CTrajectoryTask)dataModel.getTask("Time-Course");

            // run a deterministic time course
            trajectoryTask.setMethodType(CTaskEnum.Method_deterministic);

            // pass a pointer of the model to the problem
            trajectoryTask.getProblem().setModel(dataModel.getModel());

            // actiavate the task so that it will be run when the model is saved
            // and passed to CopasiSE
            trajectoryTask.setScheduled(true);

            // set the report for the task
            trajectoryTask.getReport().setReportDefinition(report);
            // set the output filename
            trajectoryTask.getReport().setTarget("example3.txt");
            // don't append output if the file exists, but overwrite the file
            trajectoryTask.getReport().setAppend(false);

            // get the problem for the task to set some parameters
            CTrajectoryProblem problem = (CTrajectoryProblem)trajectoryTask.getProblem();

            // simulate 100 steps
            problem.setStepNumber(100);
            // start at time 0
            dataModel.getModel().setInitialTime(0.0);
            // simulate a duration of 10 time units
            problem.setDuration(10);
            // tell the problem to actually generate time series data
            problem.setTimeSeriesRequested(true);

            // set some parameters for the LSODA method through the method
            CTrajectoryMethod method = (CTrajectoryMethod)trajectoryTask.getMethod();

            CCopasiParameter parameter = method.getParameter("Absolute Tolerance");
            Debug.Assert(parameter != null);
            Debug.Assert(parameter.getType() == CCopasiParameter.Type_DOUBLE);
            parameter.setDblValue(1.0e-12);

            bool result = true;
            try
            {
                // now we run the actual trajectory
                result = trajectoryTask.processWithOutputFlags(true, (int)CCopasiTask.ONLY_TIME_SERIES);
            }
            catch
            {
                System.Console.Error.WriteLine("Error. Running the time course simulation failed.");
                String lastErrors = trajectoryTask.getProcessError();
                // check if there are additional error messages
                if (!string.IsNullOrEmpty(lastErrors))
                {
                    // print the messages in chronological order
                    System.Console.Error.WriteLine(lastErrors);
                }

                System.Environment.Exit(1);
            }
            if (result == false)
            {
                System.Console.Error.WriteLine("An error occured while running the time course simulation.");
                String lastErrors = trajectoryTask.getProcessError();
                // check if there are additional error messages
                if (!string.IsNullOrEmpty(lastErrors))
                {
                    // print the messages in chronological order
                    System.Console.Error.WriteLine(lastErrors);
                }

                System.Environment.Exit(1);
            }

            // look at the timeseries
            CTimeSeries timeSeries = trajectoryTask.getTimeSeries();
            // we simulated 100 steps, including the initial state, this should be
            // 101 step in the timeseries
            Debug.Assert(timeSeries.getRecordedSteps() == 101);
            System.Console.WriteLine("The time series consists of " + System.Convert.ToString(timeSeries.getRecordedSteps()) + ".");
            System.Console.WriteLine("Each step contains " + System.Convert.ToString(timeSeries.getNumVariables()) + " variables.");
            System.Console.WriteLine("The final state is: ");
            iMax = (uint)timeSeries.getNumVariables();
            uint lastIndex = (uint)timeSeries.getRecordedSteps() - 1;
            for (i = 0; i < iMax; ++i)
            {
                // here we get the particle number (at least for the species)
                // the unit of the other variables may not be particle numbers
                // the concentration data can be acquired with getConcentrationData
                System.Console.WriteLine(timeSeries.getTitle(i) + ": " + System.Convert.ToString(timeSeries.getData(lastIndex, i)));
            }
        }
        else
        {
            System.Console.Error.WriteLine("Usage: example3 SBMLFILE");
            System.Environment.Exit(1);
        }
    }
Ejemplo n.º 3
0
    static void Main()
    {
        Debug.Assert(CRootContainer.getRoot() != null);
        // create a new datamodel
        CDataModel dataModel = CRootContainer.addDatamodel();

        Debug.Assert(CRootContainer.getDatamodelList().size() == 1);
        // get the model from the datamodel
        CModel model = dataModel.getModel();

        Debug.Assert(model != null);
        model.setVolumeUnit(CUnit.fl);
        model.setTimeUnit(CUnit.s);
        model.setQuantityUnit(CUnit.fMol);
        CModelValue fixedModelValue = model.createModelValue("F");

        Debug.Assert(fixedModelValue != null);
        fixedModelValue.setStatus(CModelEntity.Status_FIXED);
        fixedModelValue.setInitialValue(3.0);
        CModelValue variableModelValue = model.createModelValue("V");

        Debug.Assert(variableModelValue != null);
        variableModelValue.setStatus(CModelEntity.Status_ASSIGNMENT);
        // we create a very simple assignment that is easy on the optimization
        // a parabole with the minimum at x=6 should do just fine
        string s = fixedModelValue.getValueReference().getCN().getString();

        s = "(<" + s + "> - 6.0)^2";
        variableModelValue.setExpression(s);
        // now we compile the model and tell COPASI which values have changed so
        // that COPASI can update the values that depend on those
        model.compileIfNecessary();
        ObjectStdVector changedObjects = new ObjectStdVector();

        changedObjects.Add(fixedModelValue.getInitialValueReference());
        changedObjects.Add(variableModelValue.getInitialValueReference());
        model.updateInitialValues(changedObjects);

        // now we set up the optimization

        // we want to do an optimization for the time course
        // so we have to set up the time course task first
        CTrajectoryTask timeCourseTask = (CTrajectoryTask)dataModel.getTask("Time-Course");

        Debug.Assert(timeCourseTask != null);
        // since for this example it really doesn't matter how long we run the time course
        // we run for 1 second and calculate 10 steps
        // run a deterministic time course
        timeCourseTask.setMethodType(CTaskEnum.Method_deterministic);

        // pass a pointer of the model to the problem
        timeCourseTask.getProblem().setModel(dataModel.getModel());

        // get the problem for the task to set some parameters
        CTrajectoryProblem problem = (CTrajectoryProblem)timeCourseTask.getProblem();

        Debug.Assert(problem != null);

        // simulate 10 steps
        problem.setStepNumber(10);
        // start at time 0
        dataModel.getModel().setInitialTime(0.0);
        // simulate a duration of 1 time units
        problem.setDuration(1);
        // tell the problem to actually generate time series data
        problem.setTimeSeriesRequested(true);

        // get the optimization task
        COptTask optTask = (COptTask)dataModel.getTask("Optimization");

        Debug.Assert(optTask != null);
        // we want to use Levenberg-Marquardt as the optimization method
        optTask.setMethodType(CTaskEnum.Method_LevenbergMarquardt);

        // next we need to set subtask type on the problem
        COptProblem optProblem = (COptProblem)optTask.getProblem();

        Debug.Assert(optProblem != null);
        optProblem.setSubtaskType(CTaskEnum.Task_timeCourse);

        // we create the objective function
        // we want to minimize the value of the variable model value at the end of
        // the simulation
        // the objective function is normally minimized
        string objectiveFunction = variableModelValue.getObject(new CCommonName("Reference=Value")).getCN().getString();

        // we need to put the angled brackets around the common name of the object
        objectiveFunction = "<" + objectiveFunction + ">";
        // now we set the objective function in the problem
        optProblem.setObjectiveFunction(objectiveFunction);

        // now we create the optimization items
        // i.e. the model elements that have to be changed during the optimization
        // in order to get to the optimal solution
        COptItem optItem = optProblem.addOptItem(new CCommonName(fixedModelValue.getObject(new CCommonName("Reference=InitialValue")).getCN()));

        // we want to change the fixed model value from -100 to +100 with a start
        // value of 50
        optItem.setStartValue(50.0);
        optItem.setLowerBound(new CCommonName("-100"));
        optItem.setUpperBound(new CCommonName("100"));

        // now we set some parameters on the method
        // these parameters are specific to the method type we set above
        // (in this case Levenberg-Marquardt)
        COptMethod optMethod = (COptMethod)optTask.getMethod();

        Debug.Assert(optMethod != null);

        // now we set some method parameters for the optimization method
        // iteration limit
        CCopasiParameter parameter = optMethod.getParameter("Iteration Limit");

        Debug.Assert(parameter != null);
        parameter.setIntValue(2000);
        // tolerance
        parameter = optMethod.getParameter("Tolerance");
        Debug.Assert(parameter != null);
        parameter.setDblValue(1.0e-5);

        // create a report with the correct filename and all the species against
        // time.
        CReportDefinitionVector reports = dataModel.getReportDefinitionList();
        // create a new report definition object
        CReportDefinition report = reports.createReportDefinition("Report", "Output for optimization");

        // set the task type for the report definition to timecourse
        report.setTaskType(CTaskEnum.Task_optimization);
        // we don't want a table
        report.setIsTable(false);
        // the entries in the output should be seperated by a ", "
        report.setSeparator(new CCopasiReportSeparator(", "));

        // we need a handle to the header and the body
        // the header will display the ids of the metabolites and "time" for
        // the first column
        // the body will contain the actual timecourse data
        ReportItemVector header = report.getHeaderAddr();
        ReportItemVector body   = report.getBodyAddr();

        // in the report header we write two strings and a separator
        header.Add(new CRegisteredCommonName(new CDataString("best value of objective function").getCN().getString()));
        header.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
        header.Add(new CRegisteredCommonName(new CDataString("initial value of F").getCN().getString()));
        // in the report body we write the best value of the objective function and
        // the initial value of the fixed parameter separated by a komma
        body.Add(new CRegisteredCommonName(optProblem.getObject(new CCommonName("Reference=Best Value")).getCN().getString()));
        body.Add(new CRegisteredCommonName(report.getSeparator().getCN().getString()));
        body.Add(new CRegisteredCommonName(fixedModelValue.getObject(new CCommonName("Reference=InitialValue")).getCN().getString()));


        // set the report for the task
        optTask.getReport().setReportDefinition(report);
        // set the output filename
        optTask.getReport().setTarget("example5.txt");
        // don't append output if the file exists, but overwrite the file
        optTask.getReport().setAppend(false);


        bool result = false;

        try
        {
            result = optTask.processWithOutputFlags(true, (int)CCopasiTask.ONLY_TIME_SERIES);
        }
        catch (System.ApplicationException e)
        {
            System.Console.Error.WriteLine("ERROR: " + e.Message);
            String lastErrors = optTask.getProcessError();
            // check if there are additional error messages
            if (!string.IsNullOrEmpty(lastErrors))
            {
                // print the messages in chronological order
                System.Console.Error.WriteLine(lastErrors);
            }

            System.Environment.Exit(1);
        }
        if (!result)
        {
            System.Console.Error.WriteLine("Running the optimization failed.");
            String lastErrors = optTask.getProcessError();
            // check if there are additional error messages
            if (!string.IsNullOrEmpty(lastErrors))
            {
                // print the messages in chronological order
                System.Console.Error.WriteLine(lastErrors);
            }

            System.Environment.Exit(1);
        }
        // now we check if the optimization actually got the correct result
        // the best value it should have is 0 and the best parameter value for
        // that result should be 6 for the initial value of the fixed parameter
        double bestValue = optProblem.getSolutionValue();

        Debug.Assert(System.Math.Abs(bestValue) < 1e-3);
        // we should only have one solution variable since we only have one
        // optimization item
        Debug.Assert(optProblem.getSolutionVariables().size() == 1);
        double solution = optProblem.getSolutionVariables().get(0);

        Debug.Assert(System.Math.Abs((solution - 6.0) / 6.0) < 1e-3);
    }