Ejemplo n.º 1
0
        public void DoOneRun(int RunId, WeightingCombination[] i_weightingCombinations, ParameterValues parameters)
        {
            double      i_aggregatedDamage;
            ModelOutput i_output1;

            // Create Output object for run 1, set addmp to 0 so that
            // the extra greenhouse gases are not emitted and then run
            // the model
            i_output1 = new ModelOutput();

            var fundWorkflow = new Esmf.Model.ModelTyped <FundWorkflow>();

            var result1 = fundWorkflow.Run(parameters);

            i_output1.Load(result1);

            for (int i = 0; i < i_weightingCombinations.Length; i++)
            {
                i_weightingCombinations[i].CalculateWeights(i_output1);
                i_aggregatedDamage = i_weightingCombinations[i].AddDamagesUp(i_output1.Damages, _run.YearsToAggregate, _emissionYear);

                WriteAggregateDamage(RunId, i, i_aggregatedDamage, i_weightingCombinations);
            }

            //for (int l = 0; l < i_output1.Damages.Count; l++)
            //{
            //    i_Damage = i_output1.Damages[l];
            //    if ((i_Damage.Year >= _emissionYear.Value) && (i_Damage.Year < _emissionYear.Value + _run.YearsToAggregate))
            //    {
            //        for (int k = 0; k < i_weightingCombinations.Length; k++)
            //            WriteDamage(RunId, i_Damage, k, i_weightingCombinations[k][i_Damage.Year, i_Damage.Region], i_weightingCombinations);
            //    }
            //}
        }
Ejemplo n.º 2
0
        public void Run()
        {
            // Load parameters
            var parameters = new Parameters();
            parameters.ReadExcelFile(@"Data\Parameter - base.xlsm");

            // Get best guess parameter values
            var parameterValues = parameters.GetBestGuess();

            // Create a new model that inits itself from the parameters just loaded
            var model = new Esmf.Model.ModelTyped<FundWorkflow>();

            // Run the model
            var rs = model.Run(parameterValues);

            // Display all variables in interactive window
            OutputHelper.ShowModel(rs);
        }
Ejemplo n.º 3
0
        public static void Run()
        {
            int monteCarloRuns = 10000;

            // Load parameters
            var parameters = new Parameters();

            parameters.ReadExcelFile(@"Data\Parameter - base.xlsm");

            // Do one best guess run
            {
                var model = new Esmf.Model.ModelTyped <FundWorkflow>();
                //var model = new FundWorkflow(parameters.GetBestGuess());
                model.Run(parameters.GetBestGuess());
            }

            int currentRun = 0;

            var stopwatch = new Stopwatch();

            stopwatch.Start();

            ParallelMonteCarlo.DoParallelRun(
                parameters,
                monteCarloRuns,
                p =>
            {
                var m = new Esmf.Model.ModelTyped <FundWorkflow>();
                m.Run(p);

                int tempCurrentCount = Interlocked.Increment(ref currentRun);
                Console.Write("\rRun {0}                ", tempCurrentCount);

                return(0.0);
            },
                d => 0.0);

            stopwatch.Stop();

            Console.WriteLine();
            Console.WriteLine(stopwatch.Elapsed);
        }
Ejemplo n.º 4
0
        public static void Run()
        {
            int monteCarloRuns = 10000;

            // Load parameters
            var parameters = new Parameters();
            parameters.ReadExcelFile(@"Data\Parameter - base.xlsm");

            // Do one best guess run
            {
                var model = new Esmf.Model.ModelTyped<FundWorkflow>();
                //var model = new FundWorkflow(parameters.GetBestGuess());
                model.Run(parameters.GetBestGuess());
            }

            int currentRun = 0;

            var stopwatch = new Stopwatch();
            stopwatch.Start();

            ParallelMonteCarlo.DoParallelRun(
                parameters,
                monteCarloRuns,
                p =>
                {
                    var m = new Esmf.Model.ModelTyped<FundWorkflow>();
                    m.Run(p);

                    int tempCurrentCount = Interlocked.Increment(ref currentRun);
                    Console.Write("\rRun {0}                ", tempCurrentCount);

                    return 0.0;
                },
                d => 0.0);

            stopwatch.Stop();

            Console.WriteLine();
            Console.WriteLine(stopwatch.Elapsed);
        }
Ejemplo n.º 5
0
        public void TestMigrationDeterministic()
        {
            var parameterDefinition = new Parameters();
            parameterDefinition.ReadExcelFile("Parameter - Base.xlsm");
            var p = parameterDefinition.GetBestGuess();

            var m = new Esmf.Model.ModelTyped<FundWorkflow>();
            var res = m.Run(p);

            var c = new Clock(Timestep.FromYear(1951), Timestep.FromYear(2999));

            while (!c.IsLastTimestep)
            {
                var regions = res.Dimensions.GetValues<Region>();

                double totalLeave = (from r in regions select res.RootComponent.ImpactSeaLevelRise.leave[c.Current, r]).Sum();

                double totalEnter = (from r in regions select res.RootComponent.ImpactSeaLevelRise.enter[c.Current, r]).Sum();

                Assert.IsTrue(Math.Abs(totalLeave - totalEnter) < 1.0, "Migration doesn't even out");
                c.Advance();
            }
        }
        public void TestMigrationProbabalistic()
        {
            var parameterDefinition = new Parameters();

            parameterDefinition.ReadExcelFile("Parameter - Base.xlsm");
            var p = parameterDefinition.GetBestGuess();

            var m   = new Esmf.Model.ModelTyped <FundWorkflow>();
            var res = m.Run(p);

            var c = new Clock(Timestep.FromYear(1951), Timestep.FromYear(2999));

            while (!c.IsLastTimestep)
            {
                var regions = res.Dimensions.GetValues <Region>();

                double totalLeave = (from r in regions select res.RootComponent.ImpactSeaLevelRise.leave[c.Current, r]).Sum();

                double totalEnter = (from r in regions select res.RootComponent.ImpactSeaLevelRise.enter[c.Current, r]).Sum();

                Assert.IsTrue(Math.Abs(totalLeave - totalEnter) < 1.0, "Migration doesn't even out");
                c.Advance();
            }
        }
Ejemplo n.º 7
0
        public static void Run(string configurationFileName)
        {
            TextWriter gDisaggregatedCsvFile = null;

            TextWriter lAggregateMarginalDamage = null;

            TextWriter lGlobalInputCsv = null;
            TextWriter lRegionInputCsv = null;
            TextWriter lYearInputCsv = null;
            TextWriter lRegionYearInputCsv = null;

            SimulationManager lSimulationManager;

            var lDefaultConfigurationFile = Path.Combine(Path.Combine(Path.GetDirectoryName(System.Reflection.Assembly.GetExecutingAssembly().Location), "Data"), "DefaultSimulation.xml");
            lSimulationManager = new SimulationManager(configurationFileName == null ? lDefaultConfigurationFile : configurationFileName);
            lSimulationManager.Load();

            if (!Directory.Exists(ConsoleApp.OutputPath))
                Directory.CreateDirectory(ConsoleApp.OutputPath);

            var lRandom = GetNewRandom(lSimulationManager);

            lAggregateMarginalDamage = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Aggregate marginal damage.csv")));
            var TempOutputFile = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Temp.csv"));

            if (lSimulationManager.OutputVerbal)
            {
                lAggregateMarginalDamage.Write("Scenario");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Gas");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Emissionyear");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Run");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Weightingscheme");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Marginal damage");
                lAggregateMarginalDamage.WriteLine();
            }

            TextWriter lSummaryDamage = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Summary damage.csv")));

            if (lSimulationManager.OutputVerbal)
            {
                lSummaryDamage.WriteLine("Scenario;Gas;Emissionyear;Weightingscheme;Bestguess;Mean;TrimMean0.1%;TrimMean1%;TrimMean5%;Median;Std;Var;Skew;Kurt;Min;Max;SE");
            }

            if (lSimulationManager.Runs.Exists((Run r) => r.OutputDisaggregatedData))
            {
                gDisaggregatedCsvFile = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact YearRegionSectorWeightingscheme.csv")));

                if (lSimulationManager.OutputVerbal)
                {
                    gDisaggregatedCsvFile.Write("Scenario");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Run");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Marginal Gas");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Marginal Emission Year");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Year");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Region");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Sector");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Weightingscheme");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Damage");
                    gDisaggregatedCsvFile.WriteLine();
                }
            }

            using (var lDimGasCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Gas.csv")))
            {
                lDimGasCsv.WriteLine("0;C");
                lDimGasCsv.WriteLine("1;CH4");
                lDimGasCsv.WriteLine("2;N2O");
                lDimGasCsv.WriteLine("3;SF6");
            }

            using (var lDimSectorCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Sector.csv")))
            {
                lDimSectorCsv.WriteLine("0;eloss;Water");
                lDimSectorCsv.WriteLine("1;eloss;Forests");
                lDimSectorCsv.WriteLine("2;eloss;Heating");
                lDimSectorCsv.WriteLine("3;eloss;Cooling");
                lDimSectorCsv.WriteLine("4;eloss;Agriculture");
                lDimSectorCsv.WriteLine("5;eloss;Dryland");
                lDimSectorCsv.WriteLine("6;eloss;SeaProtection");
                lDimSectorCsv.WriteLine("7;eloss;Imigration");
                lDimSectorCsv.WriteLine("8;sloss;Species");
                lDimSectorCsv.WriteLine("9;sloss;Death");
                lDimSectorCsv.WriteLine("10;sloss;Morbidity");
                lDimSectorCsv.WriteLine("11;sloss;Wetland");
                lDimSectorCsv.WriteLine("12;sloss;Emigration");
                lDimSectorCsv.WriteLine("13;eloss;Hurricane");
                lDimSectorCsv.WriteLine("14;eloss;ExtratropicalStorms");
            }

            using (var lDimScenarioCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Scenario.csv")))
            {
                foreach (Scenario lScenario in lSimulationManager.Scenarios)
                {
                    // Write Scenario dimension file
                    lDimScenarioCsv.Write(lScenario.Id);
                    lDimScenarioCsv.Write(";");
                    lDimScenarioCsv.Write(lScenario.Name);
                    lDimScenarioCsv.WriteLine();
                }
            }

            using (var lDimYearCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Year.csv")))
            {
                for (int i = 1950; i <= 2300; i++)
                {
                    string lYearStr = i.ToString();
                    lDimYearCsv.Write(lYearStr);
                    lDimYearCsv.Write(";");
                    lDimYearCsv.Write(lYearStr.Substring(0, 2));
                    lDimYearCsv.Write("xx;");
                    lDimYearCsv.Write(lYearStr.Substring(0, 3));
                    lDimYearCsv.Write("x;");
                    lDimYearCsv.Write(lYearStr.Substring(0, 4));
                    lDimYearCsv.WriteLine();
                }
            }

            var lDimEmissionYear = new ConcurrentBag<Timestep>();

            if (lSimulationManager.OutputInputParameters)
            {
                lGlobalInputCsv = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact Parameter.csv")));
                lRegionInputCsv = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterRegion.csv")));
                lYearInputCsv = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterYear.csv")));
                lRegionYearInputCsv = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterYearRegion.csv")));
            }

            if (lSimulationManager.RunParallel && !lSimulationManager.SameRandomStreamPerRun)
            {
                throw new ArgumentException("Cannot run in parallel but without random stream per run");
            }

            var parallelOptions = new System.Threading.Tasks.ParallelOptions()
            {
                MaxDegreeOfParallelism = lSimulationManager.RunParallel ? -1 : 1
            };

            if (lSimulationManager.RunParallel)
            {
                var parameterDefinition = new Parameters();
                parameterDefinition.ReadExcelFile(@"Data\Parameter - base.xlsm");

                // Create a new model that inits itself from the parameters just loaded
                var model = new Esmf.Model.ModelTyped<FundWorkflow>();
                model.Run(parameterDefinition.GetBestGuess());
            }

            System.Threading.Tasks.Parallel.ForEach<Run, object>(
                lSimulationManager.Runs,
                parallelOptions,
                () =>
                {
                    Thread.CurrentThread.CurrentCulture = CultureInfo.InvariantCulture;
                    Thread.CurrentThread.Priority = ThreadPriority.BelowNormal;
                    return null;
                },
                (lRun, loopState, dummy) =>
                {
                    var tlRandom = lSimulationManager.SameRandomStreamPerRun ? GetNewRandom(lSimulationManager) : lRandom;

                    var lParam = new Parameters();

                    foreach (string filename in lRun.Scenario.ExcelFiles)
                        lParam.ReadExcelFile(filename);

                    Console.WriteLine(lRun.Scenario.Name);

                    if (lRun.Mode == RunMode.MarginalRun)
                    {
                        var lMarginalRun = new TMarginalRun(lRun, lRun.MarginalGas, lRun.EmissionYear, ConsoleApp.OutputPath, lParam, lRandom);

                        lDimEmissionYear.Add(lRun.EmissionYear);

                        lMarginalRun.AggregateDamageCsv = lAggregateMarginalDamage;
                        lMarginalRun.SummaryCsv = lSummaryDamage;

                        if (lRun.OutputDisaggregatedData)
                        {
                            lMarginalRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                        }

                        if (lSimulationManager.OutputInputParameters)
                        {
                            lMarginalRun.GlobalInputCsv = lGlobalInputCsv;
                            lMarginalRun.RegionInputCsv = lRegionInputCsv;
                            lMarginalRun.YearInputCsv = lYearInputCsv;
                            lMarginalRun.RegionYearInputCsv = lRegionYearInputCsv;
                        }

                        var watch = new System.Diagnostics.Stopwatch();
                        watch.Start();
                        lMarginalRun.Run();
                        watch.Stop();
                        //Console.WriteLine("Elapsed time: {0}", watch.Elapsed);
                    }
                    else if (lRun.Mode == RunMode.FullMarginalRun)
                    {
                        MarginalGas[] gases = { MarginalGas.C };
                        foreach (MarginalGas gas in gases)
                        {
                            for (int emissionyear = 2010; emissionyear <= 2100; emissionyear += 5)
                            {
                                lDimEmissionYear.Add(Timestep.FromYear(emissionyear));

                                Console.WriteLine("Now doing year {0} and gas {1}", emissionyear, gas);
                                // DA: Use MargMain for marginal cost, use Main for total cost and optimisation
                                // modes
                                var lMarginalRun = new TMarginalRun(lRun, gas, Timestep.FromYear(emissionyear), ConsoleApp.OutputPath, lParam, lRandom);

                                lMarginalRun.AggregateDamageCsv = lAggregateMarginalDamage;

                                if (lRun.OutputDisaggregatedData)
                                {
                                    lMarginalRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                                }

                                if (lSimulationManager.OutputInputParameters)
                                {
                                    lMarginalRun.GlobalInputCsv = lGlobalInputCsv;
                                    lMarginalRun.RegionInputCsv = lRegionInputCsv;
                                    lMarginalRun.YearInputCsv = lYearInputCsv;
                                    lMarginalRun.RegionYearInputCsv = lRegionYearInputCsv;
                                }

                                var watch = new System.Diagnostics.Stopwatch();
                                watch.Start();
                                lMarginalRun.Run();
                                watch.Stop();
                                //Console.WriteLine("Elapsed time: {0}", watch.Elapsed);
                            }
                        }
                    }
                    else if (lRun.Mode == RunMode.TotalRun)
                    {
                        // DA: Use MargMain for marginal cost, use Main for total cost and optimisation
                        // modes
                        var lTotalDamageRun = new TotalDamage(lRun, ConsoleApp.OutputPath, lParam, lRun.EmissionYear);

                        lTotalDamageRun.AggregateDamageCsv = lAggregateMarginalDamage;

                        if (lRun.OutputDisaggregatedData)
                        {
                            lTotalDamageRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                        }

                        if (lSimulationManager.OutputInputParameters)
                        {
                            lTotalDamageRun.GlobalInputCsv = lGlobalInputCsv;
                            lTotalDamageRun.RegionInputCsv = lRegionInputCsv;
                            lTotalDamageRun.YearInputCsv = lYearInputCsv;
                            lTotalDamageRun.RegionYearInputCsv = lRegionYearInputCsv;
                        }

                        lTotalDamageRun.Run();

                    }
                    return null;
                },
                (dummy) => { return; });

            lSummaryDamage.Close();
            lAggregateMarginalDamage.Close();
            TempOutputFile.Close();

            using (var lDimEmissionYearCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Emissionyear.csv")))
            {
                foreach (Timestep emissionyear in lDimEmissionYear.Distinct().OrderBy(i => i.Value))
                    lDimEmissionYearCsv.WriteLine("{0};{1}", emissionyear, emissionyear);
            }

            if (lSimulationManager.Runs.Exists((Run run) => run.OutputDisaggregatedData))
            {
                gDisaggregatedCsvFile.Close();
            }

            if (lSimulationManager.OutputInputParameters)
            {
                lGlobalInputCsv.Close();
                lRegionInputCsv.Close();
                lYearInputCsv.Close();
                lRegionYearInputCsv.Close();
            }
        }
Ejemplo n.º 8
0
        public void Start()
        {
            var run1 = new Esmf.Model.ModelTyped <FundWorkflow>();
            var run2 = new Esmf.Model.ModelTyped <FundWorkflow>();

            if (!ExpectedUtilityMode)
            {
                run1["impactaggregation"].Variables["loss"].StoreOutput      = true;
                run1["socioeconomic"].Variables["income"].StoreOutput        = true;
                run1["socioeconomic"].Variables["populationin1"].StoreOutput = true;

                run2["impactaggregation"].Variables["loss"].StoreOutput      = true;
                run2["socioeconomic"].Variables["income"].StoreOutput        = true;
                run2["socioeconomic"].Variables["populationin1"].StoreOutput = true;

                run1["ImpactWaterResources"].Variables["water"].StoreOutput   = true;
                run1["ImpactForests"].Variables["forests"].StoreOutput        = true;
                run1["ImpactHeating"].Variables["heating"].StoreOutput        = true;
                run1["ImpactCooling"].Variables["cooling"].StoreOutput        = true;
                run1["ImpactAgriculture"].Variables["agcost"].StoreOutput     = true;
                run1["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput   = true;
                run1["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput  = true;
                run1["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
                run1["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
                run1["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
                run1["ImpactBioDiversity"].Variables["species"].StoreOutput    = true;
                run1["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
                run1["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
                run1["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput    = true;
                run1["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput  = true;

                run2["ImpactWaterResources"].Variables["water"].StoreOutput   = true;
                run2["ImpactForests"].Variables["forests"].StoreOutput        = true;
                run2["ImpactHeating"].Variables["heating"].StoreOutput        = true;
                run2["ImpactCooling"].Variables["cooling"].StoreOutput        = true;
                run2["ImpactAgriculture"].Variables["agcost"].StoreOutput     = true;
                run2["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput   = true;
                run2["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput  = true;
                run2["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
                run2["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
                run2["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
                run2["ImpactBioDiversity"].Variables["species"].StoreOutput    = true;
                run2["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
                run2["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
                run2["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput    = true;
                run2["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput  = true;

                run1["socioeconomic"].Parameters["runwithoutpopulationperturbation"].SetValue(true);
                run2["socioeconomic"].Parameters["runwithoutpopulationperturbation"].SetValue(true);
            }

            if (ExpectedUtilityMode)
            {
                for (int i = 0; i < SWFs.Count; i++)
                {
                    string compName = string.Format("welfare{0}", i);
                    AddWelfareComponents(compName, run1, SWFs[i]);
                    AddWelfareComponents(compName, run2, SWFs[i]);
                }
            }

            run2.AddComponent("marginalemission", typeof(Fund.Components.MarginalEmission.MarginalEmissionComponent), typeof(Fund.Components.MarginalEmission.IMarginalEmissionState), "emissions");
            run2["marginalemission"].Parameters["emissionperiod"].SetValue(EmissionYear);
            switch (Gas)
            {
            case MarginalGas.C:
                run2["marginalemission"].Parameters["emission"].Bind("emissions", "mco2");
                run2["climateco2cycle"].Parameters["mco2"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.CH4:
                run2["marginalemission"].Parameters["emission"].Bind("emissions", "globch4");
                run2["climatech4cycle"].Parameters["globch4"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.N2O:
                run2["marginalemission"].Parameters["emission"].Bind("emissions", "globn2o");
                run2["climaten2ocycle"].Parameters["globn2o"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.SF6:
                run2["marginalemission"].Parameters["emission"].Bind("emissions", "globsf6");
                run2["climatesf6cycle"].Parameters["globsf6"].Bind("marginalemission", "modemission");
                break;

            default:
                throw new NotImplementedException();
            }

            if (AdditionalInitMethod != null)
            {
                AdditionalInitMethod(run1);
                AdditionalInitMethod(run2);
            }

            Result1 = run1.Run(Parameters);
            Result2 = run2.Run(Parameters);

            SCCs = new List <IDictionary <Region, double> >(SWFs.Count);

            if (ExpectedUtilityMode)
            {
                for (int i = 0; i < SWFs.Count; i++)
                {
                    var    swf      = SWFs[i];
                    string compName = string.Format("welfare{0}", i);
                    var    CurrSccs = new Dictionary <Region, double>();
                    SCCs.Add(CurrSccs);

                    foreach (var r in Result1.Dimensions.GetValues <Region>())
                    {
                        var sccInUtils = (swf.SWF == WelfareType.Regional || swf.SWF == WelfareType.Tol) ?
                                         (Result1[compName, "totalwelfare"][r] - Result2[compName, "totalwelfare"][r]) / 10000000.0 :
                                         (Result1[compName, "totalwelfare"] - Result2[compName, "totalwelfare"]) / 10000000.0;


                        double computedScc = (swf.SWF == WelfareType.Global || swf.SWF == WelfareType.Pearce) ?
                                             sccInUtils / (1.0 / Math.Pow(GlobalCpCAtBase, swf.Eta)) :
                                             sccInUtils / (1.0 / Math.Pow(RegionalCpCAtBase[r.Index], swf.Eta));

                        CurrSccs.Add(r, computedScc);
                    }

                    if (swf.SWF == WelfareType.Tol)
                    {
                        double computedScc = Result1.Dimensions.GetValues <Region>().Select(r => CurrSccs[r]).Sum();

                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                        {
                            CurrSccs[r] = computedScc;
                        }
                    }
                }
            }
            else
            {
                using (var mdamage = new DoubleArray(YearsToAggregate, 16))
                    using (var ypc = new DoubleArray(YearsToAggregate, 16))
                        using (var gmdamage = new DoubleArray(YearsToAggregate))
                            using (var gypc = new DoubleArray(YearsToAggregate))
                            {
                                // Extract results from model
                                for (int t = 0; t < YearsToAggregate; t++)
                                {
                                    gmdamage[t] = 0;
                                    double gincome = 0;
                                    double gpop    = 0;

                                    foreach (var r in Result1.Dimensions.GetValues <Region>())
                                    {
                                        double damage1 = (0.0
                                                          - Result1["ImpactWaterResources", "water"][EmissionYear + t, r]
                                                          - Result1["ImpactForests", "forests"][EmissionYear + t, r]
                                                          - Result1["ImpactHeating", "heating"][EmissionYear + t, r]
                                                          - Result1["ImpactCooling", "cooling"][EmissionYear + t, r]
                                                          - Result1["ImpactAgriculture", "agcost"][EmissionYear + t, r]
                                                          + Result1["ImpactSeaLevelRise", "drycost"][EmissionYear + t, r]
                                                          + Result1["ImpactSeaLevelRise", "protcost"][EmissionYear + t, r]
                                                          + Result1["ImpactSeaLevelRise", "entercost"][EmissionYear + t, r]
                                                          + Result1["ImpactTropicalStorms", "hurrdam"][EmissionYear + t, r]
                                                          + Result1["ImpactExtratropicalStorms", "extratropicalstormsdam"][EmissionYear + t, r]
                                                          + Result1["ImpactBioDiversity", "species"][EmissionYear + t, r]
                                                          + Result1["ImpactDeathMorbidity", "deadcost"][EmissionYear + t, r]
                                                          + Result1["ImpactDeathMorbidity", "morbcost"][EmissionYear + t, r]
                                                          + Result1["ImpactSeaLevelRise", "wetcost"][EmissionYear + t, r]
                                                          + Result1["ImpactSeaLevelRise", "leavecost"][EmissionYear + t, r]) * 1000000000.0;

                                        double damage2 = (0.0
                                                          - Result2["ImpactWaterResources", "water"][EmissionYear + t, r]
                                                          - Result2["ImpactForests", "forests"][EmissionYear + t, r]
                                                          - Result2["ImpactHeating", "heating"][EmissionYear + t, r]
                                                          - Result2["ImpactCooling", "cooling"][EmissionYear + t, r]
                                                          - Result2["ImpactAgriculture", "agcost"][EmissionYear + t, r]
                                                          + Result2["ImpactSeaLevelRise", "drycost"][EmissionYear + t, r]
                                                          + Result2["ImpactSeaLevelRise", "protcost"][EmissionYear + t, r]
                                                          + Result2["ImpactSeaLevelRise", "entercost"][EmissionYear + t, r]
                                                          + Result2["ImpactTropicalStorms", "hurrdam"][EmissionYear + t, r]
                                                          + Result2["ImpactExtratropicalStorms", "extratropicalstormsdam"][EmissionYear + t, r]
                                                          + Result2["ImpactBioDiversity", "species"][EmissionYear + t, r]
                                                          + Result2["ImpactDeathMorbidity", "deadcost"][EmissionYear + t, r]
                                                          + Result2["ImpactDeathMorbidity", "morbcost"][EmissionYear + t, r]
                                                          + Result2["ImpactSeaLevelRise", "wetcost"][EmissionYear + t, r]
                                                          + Result2["ImpactSeaLevelRise", "leavecost"][EmissionYear + t, r]) * 1000000000.0;


                                        double pop     = Result1["socioeconomic", "populationin1"][EmissionYear + t, r] * 1000000.0;
                                        double income1 = Result1["socioeconomic", "income"][EmissionYear + t, r] * 1000000000.0;
                                        double income2 = Result2["socioeconomic", "income"][EmissionYear + t, r] * 1000000000.0;
                                        ypc[t, r.Index] = income1 / pop;

                                        // Normalize impacts
                                        damage2 = income1 * damage2 / income2;

                                        // Compute marginal damage
                                        mdamage[t, r.Index] = (damage2 - damage1) / 10000000.0;

                                        gmdamage[t] = gmdamage[t] + mdamage[t, r.Index];
                                        gincome    += income1;
                                        gpop       += pop;
                                    }
                                    gypc[t] = gincome / gpop;
                                }


                                for (int i = 0; i < SWFs.Count; i++)
                                {
                                    var swf = SWFs[i];

                                    var CurrSccs = new Dictionary <Region, double>();
                                    SCCs.Add(CurrSccs);

                                    switch (swf.SWF)
                                    {
                                    case WelfareType.Global:
                                    {
                                        double computedScc = 0;
                                        for (int t = 0; t < YearsToAggregate; t++)
                                        {
                                            computedScc += gmdamage[t] * Math.Pow(gypc[0] / gypc[t], swf.Eta) / Math.Pow(1.0 + swf.Prtp, t);
                                        }

                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            CurrSccs.Add(r, computedScc);
                                        }
                                    }
                                    break;

                                    case WelfareType.Negishi:
                                        throw new NotImplementedException();
                                        break;

                                    case WelfareType.Pearce:
                                    {
                                        double baseYpc     = gypc[0];
                                        double computedScc = 0;
                                        for (int t = 0; t < YearsToAggregate; t++)
                                        {
                                            foreach (var r in Result1.Dimensions.GetValues <Region>())
                                            {
                                                computedScc += mdamage[t, r.Index] * Math.Pow(baseYpc / ypc[t, r.Index], swf.Eta) / Math.Pow(1.0 + swf.Prtp, t);
                                            }
                                        }

                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            CurrSccs.Add(r, computedScc);
                                        }
                                    }
                                    break;

                                    case WelfareType.Regional:
                                    {
                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            double computedScc = 0;
                                            for (int t = 0; t < YearsToAggregate; t++)
                                            {
                                                computedScc += mdamage[t, r.Index] * Math.Pow(ypc[0, r.Index] / ypc[t, r.Index], swf.Eta) / Math.Pow(1.0 + swf.Prtp, t);
                                            }
                                            CurrSccs.Add(r, computedScc);
                                        }
                                    }
                                    break;

                                    case WelfareType.Tol:
                                    {
                                        double computedScc = 0;
                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            for (int t = 0; t < YearsToAggregate; t++)
                                            {
                                                computedScc += mdamage[t, r.Index] * Math.Pow(ypc[0, r.Index] / ypc[t, r.Index], swf.Eta) / Math.Pow(1.0 + swf.Prtp, t);
                                            }
                                        }

                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            CurrSccs.Add(r, computedScc);
                                        }
                                    }

                                    break;

                                    case WelfareType.Utilitarian:
                                    {
                                        double computedScc = 0;
                                        for (int t = 0; t < YearsToAggregate; t++)
                                        {
                                            foreach (var r in Result1.Dimensions.GetValues <Region>())
                                            {
                                                computedScc += mdamage[t, r.Index] * Math.Pow(1.0 / ypc[t, r.Index], swf.Eta) / Math.Pow(1.0 + swf.Prtp, t);
                                            }
                                        }

                                        foreach (var r in Result1.Dimensions.GetValues <Region>())
                                        {
                                            CurrSccs.Add(r, computedScc * Math.Pow(ypc[0, r.Index], swf.Eta));
                                        }
                                    }
                                    break;

                                    default:
                                        throw new NotImplementedException();
                                        break;
                                    }
                                }
                            }
            }
        }
Ejemplo n.º 9
0
        public static Tuple <double, double[]> Compute2010CpC()
        {
            var parameterDefinition = new Parameters();

            parameterDefinition.ReadExcelFile(@"Data\Parameter - base.xlsm");

            var globalCpC   = new DoubleArray(monteCarloRuns);
            var regionalCpC = new DoubleArray(monteCarloRuns, 16);

            // Run model once to prep for multi tasking
            var m = new Esmf.Model.ModelTyped <FundWorkflow>();

            m["socioeconomic"].Variables["globalconsumption"].StoreOutput = true;
            m["socioeconomic"].Variables["globalpopulation"].StoreOutput  = true;
            m["socioeconomic"].Variables["consumption"].StoreOutput       = true;
            m["socioeconomic"].Variables["populationin1"].StoreOutput     = true;
            m["socioeconomic"].Parameters["runwithoutpopulationperturbation"].SetValue(true);
            m["scenariouncertainty"].Parameters["timeofuncertaintystart"].SetValue(Timestep.FromYear(2010));
            var tr   = m.Run(parameterDefinition.GetBestGuess());
            var rdim = tr.Dimensions.GetDimension <Region>();

            int currentRun = 0;

            var t2010 = Timestep.FromYear(2010);

            var rand = new jp.takel.PseudoRandom.MersenneTwister();

            Parallel.ForEach(
                parameterDefinition.GetRandom(rand, monteCarloRuns),
                () =>
            {
                Thread.CurrentThread.CurrentCulture = CultureInfo.InvariantCulture;
                Thread.CurrentThread.Priority       = ThreadPriority.BelowNormal;
                return(0);
            },
                (pv, pls, dummy) =>
            {
                int tempCurrentCount = Interlocked.Increment(ref currentRun);
                Console.Write("\rRun {0}                ", tempCurrentCount);

                var res = m.Run(pv);

                globalCpC[pv.RunId.Value - 1] = res.RootComponent.SocioEconomic.globalconsumption[t2010] / res.RootComponent.SocioEconomic.globalpopulation[t2010];

                foreach (var r in rdim.Values)
                {
                    regionalCpC[pv.RunId.Value - 1, r.Index] = res.RootComponent.SocioEconomic.consumption[t2010, r] / res.RootComponent.SocioEconomic.populationin1[t2010, r];
                }

                return(0);
            },
                (dummy) => { });

            Console.WriteLine();
            Console.WriteLine();

            double gCpCMean = globalCpC.Mean();
            double gCpCSD   = globalCpC.Std();

            var rCpCMean = new DoubleArray(16);
            var rCpCSD   = new DoubleArray(16);

            for (int i = 0; i < 16; i++)
            {
                var rCpC = regionalCpC.GetCol(i);

                rCpCMean[i] = rCpC.Mean();
                rCpCSD[i]   = rCpC.Std();
            }

            if (!Directory.Exists("Output"))
            {
                Directory.CreateDirectory("Output");
            }

            using (var f = File.CreateText(@"Output\cpc.csv"))
            {
                f.WriteLine("Region;E CpC; SD CpC");

                f.WriteLine("Global;{0:f2};{1:f2}", gCpCMean, gCpCSD);

                for (int i = 0; i < 16; i++)
                {
                    f.WriteLine("{0};{1:f2};{2:f2}", rdim.Names[i], rCpCMean[i], rCpCSD[i]);
                }
            }

            var finalResult = Tuple.Create(gCpCMean, new double[16]);

            for (int i = 0; i < 16; i++)
            {
                finalResult.Item2[i] = rCpCMean[i];
            }



            return(finalResult);
        }
Ejemplo n.º 10
0
        public static void Run()
        {
            int  yearsToAggregate = 300;
            bool expectedUtility  = false;

            double[]      prtps = { 0.001, 0.01, 0.03 };
            double[]      etas  = { 1.0, 1.5, 2.0 };
            WelfareType[] swfs  = { WelfareType.Global, WelfareType.Utilitarian, WelfareType.Regional, WelfareType.Tol, WelfareType.Pearce };

            var stopwatch = new Stopwatch();

            stopwatch.Start();

            Console.WriteLine("Computing base CpC");

            var baseCpC = Compute2010CpC();

            Console.WriteLine("Doing a run with monteCarloRuns={0}, yearsToAggregate={1}",
                              monteCarloRuns,
                              yearsToAggregate);

            var runConfigs = (from prtp in prtps
                              from eta in etas
                              from swf in swfs
                              select new RunConfig()
            {
                Prtp = prtp,
                Eta = eta,
                SWF = swf
            }).ToArray();

            string[] regions = new string[16];

            var parameterDefinition = new Parameters();

            parameterDefinition.ReadExcelFile(@"Data\Parameter - base.xlsm");

            // Run model once to prep for multi tasking
            {
                var m = new Esmf.Model.ModelTyped <FundWorkflow>();
                m.Run(parameterDefinition.GetBestGuess());
            }

            var relevantKeys = new List <ParameterElementKey>();

            foreach (var p in parameterDefinition.GetElements())
            {
                if (p is ParameterElement <double> )
                {
                    if (!(p is ParameterElementConstant <double>))
                    {
                        relevantKeys.Add(p.Key);
                    }
                }
            }

            var yValues                   = new DoubleArray[runConfigs.Length, 16];
            var correlations              = new Dictionary <ParameterElementKey, double> [runConfigs.Length, 16];
            var regressions               = new Dictionary <ParameterElementKey, double> [runConfigs.Length, 16];
            var regressionsConfIntervLow  = new Dictionary <ParameterElementKey, double> [runConfigs.Length, 16];
            var regressionsConfIntervHigh = new Dictionary <ParameterElementKey, double> [runConfigs.Length, 16];
            var regressionsFStat          = new DoubleArray(runConfigs.Length, 16);
            var regressionsPVal           = new DoubleArray(runConfigs.Length, 16);
            var regressionsRsq            = new DoubleArray(runConfigs.Length, 16);
            var xValues                   = new DoubleArray(monteCarloRuns, relevantKeys.Count);
            var standardizedXValues       = new DoubleArray(monteCarloRuns, relevantKeys.Count);
            var standardizedYValues       = new DoubleArray[runConfigs.Length, 16];

            for (int i = 0; i < runConfigs.Length; i++)
            {
                for (int l = 0; l < 16; l++)
                {
                    yValues[i, l]                   = new DoubleArray(monteCarloRuns, 1);
                    standardizedYValues[i, l]       = new DoubleArray(monteCarloRuns);
                    correlations[i, l]              = new Dictionary <ParameterElementKey, double>();
                    regressions[i, l]               = new Dictionary <ParameterElementKey, double>();
                    regressionsConfIntervHigh[i, l] = new Dictionary <ParameterElementKey, double>();
                    regressionsConfIntervLow[i, l]  = new Dictionary <ParameterElementKey, double>();
                }
            }

            var xMeans = new DoubleArray(relevantKeys.Count);
            var xStd   = new DoubleArray(relevantKeys.Count);

            var rand = new MersenneTwister();

            int currentRun = 0;

            {
                var m = new MarginalDamage2()
                {
                    EmissionYear         = Timestep.FromYear(2010),
                    Gas                  = MarginalGas.C,
                    Parameters           = parameterDefinition.GetBestGuess(),
                    YearsToAggregate     = yearsToAggregate,
                    GlobalCpCAtBase      = baseCpC.Item1,
                    ExpectedUtilityMode  = expectedUtility,
                    AdditionalInitMethod = (Esmf.Model.Model fw) =>
                    {
                        fw["scenariouncertainty"].Parameters["timeofuncertaintystart"].SetValue(Timestep.FromYear(2010));
                    }
                };

                for (int i = 0; i < 16; i++)
                {
                    m.RegionalCpCAtBase[i] = baseCpC.Item2[i];
                }

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    m.SWFs.Add(new WelfareSpec(runConfigs[i].SWF, runConfigs[i].Prtp, runConfigs[i].Eta));
                }

                m.Start();
            }

            Parallel.ForEach(
                parameterDefinition.GetRandom(rand, monteCarloRuns),
                () =>
            {
                Thread.CurrentThread.CurrentCulture = CultureInfo.InvariantCulture;
                Thread.CurrentThread.Priority       = ThreadPriority.BelowNormal;
                return(0);
            },
                (pv, pls, dummy) =>
            {
                int tempCurrentCount = Interlocked.Increment(ref currentRun);
                Console.Write("\rRun {0}                ", tempCurrentCount);

                var m = new MarginalDamage2()
                {
                    EmissionYear         = Timestep.FromYear(2010),
                    Gas                  = MarginalGas.C,
                    Parameters           = pv,
                    YearsToAggregate     = yearsToAggregate,
                    GlobalCpCAtBase      = baseCpC.Item1,
                    ExpectedUtilityMode  = false,
                    AdditionalInitMethod = (Esmf.Model.Model fw) =>
                    {
                        fw["scenariouncertainty"].Parameters["timeofuncertaintystart"].SetValue(Timestep.FromYear(2010));
                    }
                };

                for (int i = 0; i < 16; i++)
                {
                    m.RegionalCpCAtBase[i] = baseCpC.Item2[i];
                }

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    m.SWFs.Add(new WelfareSpec(runConfigs[i].SWF, runConfigs[i].Prtp, runConfigs[i].Eta));
                }

                m.Start();

                var dimensions = m.Result1.Dimensions;

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    foreach (var r in dimensions.GetValues <Region>())
                    {
                        regions[r.Index] = r.ToString();
                        yValues[i, r.Index][(int)pv.RunId - 1] = m.SCCs[i][r];
                    }
                }

                for (int l = 0; l < relevantKeys.Count; l++)
                {
                    var p      = relevantKeys[l];
                    double val = ((ParameterValueElement <double>)pv.GetElementByKey(p)).Value;

                    xValues[pv.RunId.Value - 1, l] = val;
                }

                return(0);
            },
                (dummy) => { });

            Console.WriteLine();
            Console.WriteLine();

            if (!Directory.Exists("Output"))
            {
                Directory.CreateDirectory("Output");
            }

            Console.WriteLine("Write summary");

            // Output summary
            using (var f = File.CreateText(@"Output\summary.csv"))
            {
                f.WriteLine("Prtp;Eta;Swf;SccRegion;Mean;Variance;StdDev;StandardError");

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        double standardError = yValues[i, l].Std() / Math.Sqrt(monteCarloRuns);
                        f.WriteLine("{0};{1};{2:f3};{3:f3};{4:f3};{5:f3}",
                                    runConfigs[i],
                                    regions[l],
                                    yValues[i, l].Mean(),
                                    yValues[i, l].Var(),
                                    yValues[i, l].Std(),
                                    standardError);
                    }
                }
            }

            Console.WriteLine("Compute correlations");

            // Compute correlations
            for (int k = 0; k < relevantKeys.Count; k++)
            {
                var xSlice = xValues.GetCol(k);

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        // Compute correlation between parameter i and SCC
                        var    pearson = new Pearson(yValues[i, l], xSlice);
                        double corr    = (double)pearson.Rho;
                        correlations[i, l].Add(relevantKeys[k], corr);
                    }
                }
            }

            Console.WriteLine("Compute regressions");

            // Standardize everything
            for (int k = 0; k < relevantKeys.Count; k++)
            {
                var xSlice = xValues.GetCol(k);

                xMeans[k] = xSlice.Mean();
                xStd[k]   = xSlice.Std();
            }

            for (int k = 0; k < monteCarloRuns; k++)
            {
                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        standardizedYValues[i, l][k] = (yValues[i, l][k] - yValues[i, l].Mean()) / yValues[i, l].Std();
                    }
                }

                for (int l = 0; l < relevantKeys.Count; l++)
                {
                    standardizedXValues[k, l] = (xValues[k, l] - xMeans[l]) / xStd[l];
                }
            }

            // Compute regression
            for (int i = 0; i < runConfigs.Length; i++)
            {
                for (int l = 0; l < 16; l++)
                {
                    var regress = new Regress(standardizedYValues[i, l], standardizedXValues, 0.1);

                    regressionsFStat[i, l] = regress.FStat;
                    regressionsPVal[i, l]  = regress.PVal;
                    regressionsRsq[i, l]   = regress.Rsq;

                    for (int k = 0; k < relevantKeys.Count; k++)
                    {
                        regressions[i, l].Add(relevantKeys[k], regress.Beta[k + 1]);

                        regressionsConfIntervLow[i, l].Add(relevantKeys[k], regress.BetaInt[k + 1, 0]);
                        regressionsConfIntervHigh[i, l].Add(relevantKeys[k], regress.BetaInt[k + 1, 1]);
                    }
                }
            }

            Console.WriteLine("Write regression summary");

            // Write regression summaries
            using (var f = File.CreateText(@"Output\regression summary.csv"))
            {
                f.WriteLine("Prtp;Eta;Swf;SccRegion;FStat;PVal;Rsq");

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        f.WriteLine("{0};{1};{2:f15};{3:f15};{4:f15}", runConfigs[i], regions[l], regressionsFStat[i, l], regressionsPVal[i, l], regressionsRsq[i, l]);
                    }
                }
            }

            Console.WriteLine("Write correlation");

            // Write correlation
            using (var f = File.CreateText(@"Output\correlation.csv"))
            {
                f.WriteLine("Prtp;Eta;Swf;SccRegion;Name;Correlation;RegressCoefficient;RegressConfIntLower;RegressConfIntUpper");

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        foreach (var key in relevantKeys)
                        {
                            string s = key.Name;
                            if (key is ParameterElementKey1Dimensional)
                            {
                                s += "-" + regions[((ParameterElementKey1Dimensional)key).D1];
                            }
                            else if (key is ParameterElementKey2Dimensional)
                            {
                                s += "-" + regions[((ParameterElementKey2Dimensional)key).D1] + "-" + regions[((ParameterElementKey2Dimensional)key).D2];
                            }

                            f.WriteLine("{0};{1};\"{2}\";{3:f10};{4:f10};{5:f10};{6:f10}", runConfigs[i], regions[l], s, correlations[i, l][key], regressions[i, l][key], regressionsConfIntervLow[i, l][key], regressionsConfIntervHigh[i, l][key]);
                        }
                    }
                }
            }

            Console.WriteLine("Write SCC values");

            using (var f = File.CreateText(@"Output\scc values.csv"))
            {
                f.WriteLine("Prtp;Eta;Swf;SccRegion;RundId;Scc");

                for (int i = 0; i < runConfigs.Length; i++)
                {
                    for (int l = 0; l < 16; l++)
                    {
                        for (int k = 0; k < monteCarloRuns; k++)
                        {
                            double standardError = yValues[i, l].Std() / Math.Sqrt(monteCarloRuns);
                            f.WriteLine("{0};{1};{2};{3:f14}",
                                        runConfigs[i],
                                        regions[l],
                                        k,
                                        yValues[i, l][k]);
                        }
                    }
                }
            }

            stopwatch.Stop();

            Console.WriteLine(stopwatch.Elapsed);
        }
Ejemplo n.º 11
0
        public static void Run(string configurationFileName)
        {
            TextWriter gDisaggregatedCsvFile = null;

            TextWriter lAggregateMarginalDamage = null;

            TextWriter lGlobalInputCsv     = null;
            TextWriter lRegionInputCsv     = null;
            TextWriter lYearInputCsv       = null;
            TextWriter lRegionYearInputCsv = null;

            SimulationManager lSimulationManager;

            var lDefaultConfigurationFile = Path.Combine(Path.Combine(Path.GetDirectoryName(System.Reflection.Assembly.GetExecutingAssembly().Location), "Data"), "DefaultSimulation.xml");

            lSimulationManager = new SimulationManager(configurationFileName == null ? lDefaultConfigurationFile : configurationFileName);
            lSimulationManager.Load();

            if (!Directory.Exists(ConsoleApp.OutputPath))
            {
                Directory.CreateDirectory(ConsoleApp.OutputPath);
            }

            var lRandom = GetNewRandom(lSimulationManager);

            lAggregateMarginalDamage = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Aggregate marginal damage.csv")));
            var TempOutputFile = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Temp.csv"));

            if (lSimulationManager.OutputVerbal)
            {
                lAggregateMarginalDamage.Write("Scenario");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Gas");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Emissionyear");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Run");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Weightingscheme");
                lAggregateMarginalDamage.Write(";");
                lAggregateMarginalDamage.Write("Marginal damage");
                lAggregateMarginalDamage.WriteLine();
            }

            TextWriter lSummaryDamage = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Summary damage.csv")));

            if (lSimulationManager.OutputVerbal)
            {
                lSummaryDamage.WriteLine("Scenario;Gas;Emissionyear;Weightingscheme;Bestguess;Mean;TrimMean0.1%;TrimMean1%;TrimMean5%;Median;Std;Var;Skew;Kurt;Min;Max;SE");
            }


            if (lSimulationManager.Runs.Exists((Run r) => r.OutputDisaggregatedData))
            {
                gDisaggregatedCsvFile = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact YearRegionSectorWeightingscheme.csv")));

                if (lSimulationManager.OutputVerbal)
                {
                    gDisaggregatedCsvFile.Write("Scenario");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Run");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Marginal Gas");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Marginal Emission Year");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Year");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Region");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Sector");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Weightingscheme");
                    gDisaggregatedCsvFile.Write(";");
                    gDisaggregatedCsvFile.Write("Damage");
                    gDisaggregatedCsvFile.WriteLine();
                }
            }

            using (var lDimGasCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Gas.csv")))
            {
                lDimGasCsv.WriteLine("0;C");
                lDimGasCsv.WriteLine("1;CH4");
                lDimGasCsv.WriteLine("2;N2O");
                lDimGasCsv.WriteLine("3;SF6");
            }

            using (var lDimSectorCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Sector.csv")))
            {
                lDimSectorCsv.WriteLine("0;eloss;Water");
                lDimSectorCsv.WriteLine("1;eloss;Forests");
                lDimSectorCsv.WriteLine("2;eloss;Heating");
                lDimSectorCsv.WriteLine("3;eloss;Cooling");
                lDimSectorCsv.WriteLine("4;eloss;Agriculture");
                lDimSectorCsv.WriteLine("5;eloss;Dryland");
                lDimSectorCsv.WriteLine("6;eloss;SeaProtection");
                lDimSectorCsv.WriteLine("7;eloss;Imigration");
                lDimSectorCsv.WriteLine("8;sloss;Species");
                lDimSectorCsv.WriteLine("9;sloss;Death");
                lDimSectorCsv.WriteLine("10;sloss;Morbidity");
                lDimSectorCsv.WriteLine("11;sloss;Wetland");
                lDimSectorCsv.WriteLine("12;sloss;Emigration");
                lDimSectorCsv.WriteLine("13;eloss;Hurricane");
                lDimSectorCsv.WriteLine("14;eloss;ExtratropicalStorms");
            }


            using (var lDimScenarioCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Scenario.csv")))
            {
                foreach (Scenario lScenario in lSimulationManager.Scenarios)
                {
                    // Write Scenario dimension file
                    lDimScenarioCsv.Write(lScenario.Id);
                    lDimScenarioCsv.Write(";");
                    lDimScenarioCsv.Write(lScenario.Name);
                    lDimScenarioCsv.WriteLine();
                }
            }


            using (var lDimYearCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Year.csv")))
            {
                for (int i = 1950; i <= 2300; i++)
                {
                    string lYearStr = i.ToString();
                    lDimYearCsv.Write(lYearStr);
                    lDimYearCsv.Write(";");
                    lDimYearCsv.Write(lYearStr.Substring(0, 2));
                    lDimYearCsv.Write("xx;");
                    lDimYearCsv.Write(lYearStr.Substring(0, 3));
                    lDimYearCsv.Write("x;");
                    lDimYearCsv.Write(lYearStr.Substring(0, 4));
                    lDimYearCsv.WriteLine();
                }
            }

            var lDimEmissionYear = new ConcurrentBag <Timestep>();

            if (lSimulationManager.OutputInputParameters)
            {
                lGlobalInputCsv     = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact Parameter.csv")));
                lRegionInputCsv     = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterRegion.csv")));
                lYearInputCsv       = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterYear.csv")));
                lRegionYearInputCsv = TextWriter.Synchronized(new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Fact ParameterYearRegion.csv")));
            }

            if (lSimulationManager.RunParallel && !lSimulationManager.SameRandomStreamPerRun)
            {
                throw new ArgumentException("Cannot run in parallel but without random stream per run");
            }

            var parallelOptions = new System.Threading.Tasks.ParallelOptions()
            {
                MaxDegreeOfParallelism = lSimulationManager.RunParallel ? -1 : 1
            };

            if (lSimulationManager.RunParallel)
            {
                var parameterDefinition = new Parameters();
                parameterDefinition.ReadExcelFile(@"Data\Parameter - base.xlsm");

                // Create a new model that inits itself from the parameters just loaded
                var model = new Esmf.Model.ModelTyped <FundWorkflow>();
                model.Run(parameterDefinition.GetBestGuess());
            }

            System.Threading.Tasks.Parallel.ForEach <Run, object>(
                lSimulationManager.Runs,
                parallelOptions,
                () =>
            {
                Thread.CurrentThread.CurrentCulture = CultureInfo.InvariantCulture;
                Thread.CurrentThread.Priority       = ThreadPriority.BelowNormal;
                return(null);
            },
                (lRun, loopState, dummy) =>
            {
                var tlRandom = lSimulationManager.SameRandomStreamPerRun ? GetNewRandom(lSimulationManager) : lRandom;

                var lParam = new Parameters();

                foreach (string filename in lRun.Scenario.ExcelFiles)
                {
                    lParam.ReadExcelFile(filename);
                }

                Console.WriteLine(lRun.Scenario.Name);

                if (lRun.Mode == RunMode.MarginalRun)
                {
                    var lMarginalRun = new TMarginalRun(lRun, lRun.MarginalGas, lRun.EmissionYear, ConsoleApp.OutputPath, lParam, lRandom);

                    lDimEmissionYear.Add(lRun.EmissionYear);

                    lMarginalRun.AggregateDamageCsv = lAggregateMarginalDamage;
                    lMarginalRun.SummaryCsv         = lSummaryDamage;

                    if (lRun.OutputDisaggregatedData)
                    {
                        lMarginalRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                    }

                    if (lSimulationManager.OutputInputParameters)
                    {
                        lMarginalRun.GlobalInputCsv     = lGlobalInputCsv;
                        lMarginalRun.RegionInputCsv     = lRegionInputCsv;
                        lMarginalRun.YearInputCsv       = lYearInputCsv;
                        lMarginalRun.RegionYearInputCsv = lRegionYearInputCsv;
                    }

                    var watch = new System.Diagnostics.Stopwatch();
                    watch.Start();
                    lMarginalRun.Run();
                    watch.Stop();
                    //Console.WriteLine("Elapsed time: {0}", watch.Elapsed);
                }
                else if (lRun.Mode == RunMode.FullMarginalRun)
                {
                    MarginalGas[] gases = { MarginalGas.C };
                    foreach (MarginalGas gas in gases)
                    {
                        for (int emissionyear = 2010; emissionyear <= 2100; emissionyear += 5)
                        {
                            lDimEmissionYear.Add(Timestep.FromYear(emissionyear));

                            Console.WriteLine("Now doing year {0} and gas {1}", emissionyear, gas);
                            // DA: Use MargMain for marginal cost, use Main for total cost and optimisation
                            // modes
                            var lMarginalRun = new TMarginalRun(lRun, gas, Timestep.FromYear(emissionyear), ConsoleApp.OutputPath, lParam, lRandom);

                            lMarginalRun.AggregateDamageCsv = lAggregateMarginalDamage;

                            if (lRun.OutputDisaggregatedData)
                            {
                                lMarginalRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                            }

                            if (lSimulationManager.OutputInputParameters)
                            {
                                lMarginalRun.GlobalInputCsv     = lGlobalInputCsv;
                                lMarginalRun.RegionInputCsv     = lRegionInputCsv;
                                lMarginalRun.YearInputCsv       = lYearInputCsv;
                                lMarginalRun.RegionYearInputCsv = lRegionYearInputCsv;
                            }

                            var watch = new System.Diagnostics.Stopwatch();
                            watch.Start();
                            lMarginalRun.Run();
                            watch.Stop();
                            //Console.WriteLine("Elapsed time: {0}", watch.Elapsed);
                        }
                    }
                }
                else if (lRun.Mode == RunMode.TotalRun)
                {
                    // DA: Use MargMain for marginal cost, use Main for total cost and optimisation
                    // modes
                    var lTotalDamageRun = new TotalDamage(lRun, ConsoleApp.OutputPath, lParam, lRun.EmissionYear);

                    lTotalDamageRun.AggregateDamageCsv = lAggregateMarginalDamage;

                    if (lRun.OutputDisaggregatedData)
                    {
                        lTotalDamageRun.YearRegionSectorWeightingSchemeCsv = gDisaggregatedCsvFile;
                    }

                    if (lSimulationManager.OutputInputParameters)
                    {
                        lTotalDamageRun.GlobalInputCsv     = lGlobalInputCsv;
                        lTotalDamageRun.RegionInputCsv     = lRegionInputCsv;
                        lTotalDamageRun.YearInputCsv       = lYearInputCsv;
                        lTotalDamageRun.RegionYearInputCsv = lRegionYearInputCsv;
                    }

                    lTotalDamageRun.Run();
                }
                return(null);
            },
                (dummy) => { return; });

            lSummaryDamage.Close();
            lAggregateMarginalDamage.Close();
            TempOutputFile.Close();

            using (var lDimEmissionYearCsv = new StreamWriter(Path.Combine(ConsoleApp.OutputPath, "Output - Dim Emissionyear.csv")))
            {
                foreach (Timestep emissionyear in lDimEmissionYear.Distinct().OrderBy(i => i.Value))
                {
                    lDimEmissionYearCsv.WriteLine("{0};{1}", emissionyear, emissionyear);
                }
            }

            if (lSimulationManager.Runs.Exists((Run run) => run.OutputDisaggregatedData))
            {
                gDisaggregatedCsvFile.Close();
            }

            if (lSimulationManager.OutputInputParameters)
            {
                lGlobalInputCsv.Close();
                lRegionInputCsv.Close();
                lYearInputCsv.Close();
                lRegionYearInputCsv.Close();
            }
        }
Ejemplo n.º 12
0
        public double[] DoOneRun(int RunId, WeightingCombination[] i_weightingCombinations, ParameterValues parameters)
        {
            ModelOutput i_output2;
            Damages i_marginalDamages;
            double i_aggregatedDamage;
            ModelOutput i_output1;

            // Create Output object for run 1, set addmp to 0 so that
            // the extra greenhouse gases are not emitted and then run
            // the model
            i_output1 = new ModelOutput();

            var f1 = new Esmf.Model.ModelTyped<FundWorkflow>();
            f1["ImpactWaterResources"].Variables["water"].StoreOutput = true;
            f1["ImpactForests"].Variables["forests"].StoreOutput = true;
            f1["ImpactHeating"].Variables["heating"].StoreOutput = true;
            f1["ImpactCooling"].Variables["cooling"].StoreOutput = true;
            f1["ImpactAgriculture"].Variables["agcost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
            f1["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
            f1["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
            f1["ImpactBioDiversity"].Variables["species"].StoreOutput = true;
            f1["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
            f1["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput = true;
            f1["SocioEconomic"].Variables["income"].StoreOutput = true;
            f1["SocioEconomic"].Variables["population"].StoreOutput = true;

            if (AdditionalInitCode != null)
                AdditionalInitCode(f1);

            var result1 = f1.Run(parameters);

            i_output1.Load(result1);

            // Create Output object for run 2, set addmp to 1 so that
            // the extra greenhouse gases for the marginal run are
            // emitted and then run the model
            i_output2 = new ModelOutput();

            var f2 = new Esmf.Model.ModelTyped<FundWorkflow>();
            f2["ImpactWaterResources"].Variables["water"].StoreOutput = true;
            f2["ImpactForests"].Variables["forests"].StoreOutput = true;
            f2["ImpactHeating"].Variables["heating"].StoreOutput = true;
            f2["ImpactCooling"].Variables["cooling"].StoreOutput = true;
            f2["ImpactAgriculture"].Variables["agcost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
            f2["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
            f2["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
            f2["ImpactBioDiversity"].Variables["species"].StoreOutput = true;
            f2["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
            f2["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput = true;
            f2["SocioEconomic"].Variables["income"].StoreOutput = true;
            f2["SocioEconomic"].Variables["population"].StoreOutput = true;

            if (AdditionalInitCode != null)
                AdditionalInitCode(f2);

            f2.AddComponent("marginalemission", typeof(Fund.Components.MarginalEmission.MarginalEmissionComponent), typeof(Fund.Components.MarginalEmission.IMarginalEmissionState), "emissions");
            f2["marginalemission"].Parameters["emissionperiod"].SetValue(_emissionyear);
            switch (_gas)
            {
                case MarginalGas.C:
                    f2["marginalemission"].Parameters["emission"].Bind("emissions", "mco2");
                    f2["climateco2cycle"].Parameters["mco2"].Bind("marginalemission", "modemission");
                    break;
                case MarginalGas.CH4:
                    f2["marginalemission"].Parameters["emission"].Bind("emissions", "globch4");
                    f2["climatech4cycle"].Parameters["globch4"].Bind("marginalemission", "modemission");
                    break;
                case MarginalGas.N2O:
                    f2["marginalemission"].Parameters["emission"].Bind("emissions", "globn2o");
                    f2["climaten2ocycle"].Parameters["globn2o"].Bind("marginalemission", "modemission");
                    break;
                case MarginalGas.SF6:
                    f2["marginalemission"].Parameters["emission"].Bind("emissions", "globsf6");
                    f2["climatesf6cycle"].Parameters["globsf6"].Bind("marginalemission", "modemission");
                    break;
                default:
                    throw new NotImplementedException();
            }

            var result2 = f2.Run(parameters);

            i_output2.Load(result2);

            Fund28LegacyWeightingCombinations.GetWeightingCombinationsFromName(_run.WeightingCombination, out i_weightingCombinations, _emissionyear);

            // Take out growth effect effect of run 2 by transforming
            // the damage from run 2 into % of GDP of run 2, and then
            // multiplying that with GDP of run 1
            for (int year = 1; year < LegacyConstants.NYear; year++)
            {
                for (int region = 0; region < LegacyConstants.NoReg; region++)
                {
                    for (int sector = 0; sector < LegacyConstants.NoSector; sector++)
                    {
                        i_output2.Damages[year, region, (Sector)sector] = (i_output2.Damages[year, region, (Sector)sector] / i_output2.Incomes[year, region]) * i_output1.Incomes[year, region];
                    }
                }
            }

            // Calculate the marginal damage between run 1 and 2 for each
            // year/region/sector
            i_marginalDamages = Damages.CalculateMarginalDamage(i_output1.Damages, i_output2.Damages);

            double[] i_weightedAggregatedDamages = new double[i_weightingCombinations.Length];

            for (int i = 0; i < i_weightingCombinations.Length; i++)
            {
                i_weightingCombinations[i].CalculateWeights(i_output1);
                i_aggregatedDamage = i_weightingCombinations[i].AddDamagesUp(i_marginalDamages, _run.YearsToAggregate, _emissionyear);

                i_weightedAggregatedDamages[i] = i_aggregatedDamage;

                WriteAggregateDamage(RunId, i, i_aggregatedDamage, i_weightingCombinations);

                // Console.Write(i_weightingCombinations[i].Name + ": ");
                // Console.WriteLine(Convert.ToString(i_aggregatedDamage));
            }

            if (m_YearRegionSectorWeightingSchemeCsv != null)
            {
                foreach (var i_Damage in i_marginalDamages)
                {
                    if ((i_Damage.Year >= _emissionyear.Value) && (i_Damage.Year < _emissionyear.Value + _run.YearsToAggregate))
                    {
                        for (int k = 0; k < i_weightingCombinations.Length; k++)
                            WriteMarginalDamage(RunId, i_Damage, k, i_weightingCombinations[k][i_Damage.Year, i_Damage.Region], i_weightingCombinations);
                    }
                }
            }

            return i_weightedAggregatedDamages;
        }
Ejemplo n.º 13
0
        public void DoOneRun(int RunId, WeightingCombination[] i_weightingCombinations, ParameterValues parameters)
        {
            double i_aggregatedDamage;
            ModelOutput i_output1;

            // Create Output object for run 1, set addmp to 0 so that
            // the extra greenhouse gases are not emitted and then run
            // the model
            i_output1 = new ModelOutput();

            var fundWorkflow = new Esmf.Model.ModelTyped<FundWorkflow>();

            var result1 = fundWorkflow.Run(parameters);

            i_output1.Load(result1);

            for (int i = 0; i < i_weightingCombinations.Length; i++)
            {
                i_weightingCombinations[i].CalculateWeights(i_output1);
                i_aggregatedDamage = i_weightingCombinations[i].AddDamagesUp(i_output1.Damages, _run.YearsToAggregate, _emissionYear);

                WriteAggregateDamage(RunId, i, i_aggregatedDamage, i_weightingCombinations);

            }

            //for (int l = 0; l < i_output1.Damages.Count; l++)
            //{
            //    i_Damage = i_output1.Damages[l];
            //    if ((i_Damage.Year >= _emissionYear.Value) && (i_Damage.Year < _emissionYear.Value + _run.YearsToAggregate))
            //    {
            //        for (int k = 0; k < i_weightingCombinations.Length; k++)
            //            WriteDamage(RunId, i_Damage, k, i_weightingCombinations[k][i_Damage.Year, i_Damage.Region], i_weightingCombinations);
            //    }
            //}
        }
        public double[] DoOneRun(int RunId, WeightingCombination[] i_weightingCombinations, ParameterValues parameters)
        {
            ModelOutput i_output2;
            Damages     i_marginalDamages;
            double      i_aggregatedDamage;
            ModelOutput i_output1;

            // Create Output object for run 1, set addmp to 0 so that
            // the extra greenhouse gases are not emitted and then run
            // the model
            i_output1 = new ModelOutput();

            var f1 = new Esmf.Model.ModelTyped <FundWorkflow>();

            f1["ImpactWaterResources"].Variables["water"].StoreOutput   = true;
            f1["ImpactForests"].Variables["forests"].StoreOutput        = true;
            f1["ImpactHeating"].Variables["heating"].StoreOutput        = true;
            f1["ImpactCooling"].Variables["cooling"].StoreOutput        = true;
            f1["ImpactAgriculture"].Variables["agcost"].StoreOutput     = true;
            f1["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput   = true;
            f1["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput  = true;
            f1["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
            f1["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
            f1["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
            f1["ImpactBioDiversity"].Variables["species"].StoreOutput    = true;
            f1["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
            f1["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
            f1["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput    = true;
            f1["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput  = true;
            f1["SocioEconomic"].Variables["income"].StoreOutput          = true;
            f1["SocioEconomic"].Variables["population"].StoreOutput      = true;

            if (AdditionalInitCode != null)
            {
                AdditionalInitCode(f1);
            }

            var result1 = f1.Run(parameters);

            i_output1.Load(result1);

            // Create Output object for run 2, set addmp to 1 so that
            // the extra greenhouse gases for the marginal run are
            // emitted and then run the model
            i_output2 = new ModelOutput();

            var f2 = new Esmf.Model.ModelTyped <FundWorkflow>();

            f2["ImpactWaterResources"].Variables["water"].StoreOutput   = true;
            f2["ImpactForests"].Variables["forests"].StoreOutput        = true;
            f2["ImpactHeating"].Variables["heating"].StoreOutput        = true;
            f2["ImpactCooling"].Variables["cooling"].StoreOutput        = true;
            f2["ImpactAgriculture"].Variables["agcost"].StoreOutput     = true;
            f2["ImpactSeaLevelRise"].Variables["drycost"].StoreOutput   = true;
            f2["ImpactSeaLevelRise"].Variables["protcost"].StoreOutput  = true;
            f2["ImpactSeaLevelRise"].Variables["entercost"].StoreOutput = true;
            f2["ImpactTropicalStorms"].Variables["hurrdam"].StoreOutput = true;
            f2["ImpactExtratropicalStorms"].Variables["extratropicalstormsdam"].StoreOutput = true;
            f2["ImpactBioDiversity"].Variables["species"].StoreOutput    = true;
            f2["ImpactDeathMorbidity"].Variables["deadcost"].StoreOutput = true;
            f2["ImpactDeathMorbidity"].Variables["morbcost"].StoreOutput = true;
            f2["ImpactSeaLevelRise"].Variables["wetcost"].StoreOutput    = true;
            f2["ImpactSeaLevelRise"].Variables["leavecost"].StoreOutput  = true;
            f2["SocioEconomic"].Variables["income"].StoreOutput          = true;
            f2["SocioEconomic"].Variables["population"].StoreOutput      = true;

            if (AdditionalInitCode != null)
            {
                AdditionalInitCode(f2);
            }

            f2.AddComponent("marginalemission", typeof(Fund.Components.MarginalEmission.MarginalEmissionComponent), typeof(Fund.Components.MarginalEmission.IMarginalEmissionState), "emissions");
            f2["marginalemission"].Parameters["emissionperiod"].SetValue(_emissionyear);
            switch (_gas)
            {
            case MarginalGas.C:
                f2["marginalemission"].Parameters["emission"].Bind("emissions", "mco2");
                f2["climateco2cycle"].Parameters["mco2"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.CH4:
                f2["marginalemission"].Parameters["emission"].Bind("emissions", "globch4");
                f2["climatech4cycle"].Parameters["globch4"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.N2O:
                f2["marginalemission"].Parameters["emission"].Bind("emissions", "globn2o");
                f2["climaten2ocycle"].Parameters["globn2o"].Bind("marginalemission", "modemission");
                break;

            case MarginalGas.SF6:
                f2["marginalemission"].Parameters["emission"].Bind("emissions", "globsf6");
                f2["climatesf6cycle"].Parameters["globsf6"].Bind("marginalemission", "modemission");
                break;

            default:
                throw new NotImplementedException();
            }

            var result2 = f2.Run(parameters);

            i_output2.Load(result2);

            Fund28LegacyWeightingCombinations.GetWeightingCombinationsFromName(_run.WeightingCombination, out i_weightingCombinations, _emissionyear);

            // Take out growth effect effect of run 2 by transforming
            // the damage from run 2 into % of GDP of run 2, and then
            // multiplying that with GDP of run 1
            for (int year = 1; year < LegacyConstants.NYear; year++)
            {
                for (int region = 0; region < LegacyConstants.NoReg; region++)
                {
                    for (int sector = 0; sector < LegacyConstants.NoSector; sector++)
                    {
                        i_output2.Damages[year, region, (Sector)sector] = (i_output2.Damages[year, region, (Sector)sector] / i_output2.Incomes[year, region]) * i_output1.Incomes[year, region];
                    }
                }
            }

            // Calculate the marginal damage between run 1 and 2 for each
            // year/region/sector
            i_marginalDamages = Damages.CalculateMarginalDamage(i_output1.Damages, i_output2.Damages);

            double[] i_weightedAggregatedDamages = new double[i_weightingCombinations.Length];

            for (int i = 0; i < i_weightingCombinations.Length; i++)
            {
                i_weightingCombinations[i].CalculateWeights(i_output1);
                i_aggregatedDamage = i_weightingCombinations[i].AddDamagesUp(i_marginalDamages, _run.YearsToAggregate, _emissionyear);

                i_weightedAggregatedDamages[i] = i_aggregatedDamage;

                WriteAggregateDamage(RunId, i, i_aggregatedDamage, i_weightingCombinations);

                // Console.Write(i_weightingCombinations[i].Name + ": ");
                // Console.WriteLine(Convert.ToString(i_aggregatedDamage));
            }

            if (m_YearRegionSectorWeightingSchemeCsv != null)
            {
                foreach (var i_Damage in i_marginalDamages)
                {
                    if ((i_Damage.Year >= _emissionyear.Value) && (i_Damage.Year < _emissionyear.Value + _run.YearsToAggregate))
                    {
                        for (int k = 0; k < i_weightingCombinations.Length; k++)
                        {
                            WriteMarginalDamage(RunId, i_Damage, k, i_weightingCombinations[k][i_Damage.Year, i_Damage.Region], i_weightingCombinations);
                        }
                    }
                }
            }

            return(i_weightedAggregatedDamages);
        }