/home/hudson/saved_omc/OMSimulator/install/bin/OMSimulator  --tempDir=temp_Physiolibrary_Physiolibrary_Fluid_Examples_MeanRespiration_fmu --startTime=0 --stopTime=1800 --stepSize=0.72 --timeout=50 --tolerance=1e-06 Physiolibrary_Physiolibrary_Fluid_Examples_MeanRespiration.fmu
warning: Failed to load settings: [json.exception.parse_error.101] parse error at line 4, column 1: syntax error while parsing value - unexpected '}'; expected end of input
warning: Failed to save settings: [json.exception.parse_error.101] parse error at line 4, column 1: syntax error while parsing value - unexpected '}'; expected end of input
info:    Set temp directory to    "/var/lib/jenkins1/ws/OpenModelicaLibraryTestingWork_2/OpenModelicaLibraryTesting/Physiolibrary_Physiolibrary.Fluid.Examples.MeanRespiration"
info:    Set working directory to "/var/lib/jenkins1/ws/OpenModelicaLibraryTestingWork_2/OpenModelicaLibraryTesting/Physiolibrary_Physiolibrary.Fluid.Examples.MeanRespiration"
info:    New model "model" with corresponding temp directory "/var/lib/jenkins1/ws/OpenModelicaLibraryTestingWork_2/OpenModelicaLibraryTesting/Physiolibrary_Physiolibrary.Fluid.Examples.MeanRespiration/model-2bjqar2u"
info:    *** FMU Simulation Info ***
          - model:     model (model exchange)
          - path:      Physiolibrary_Physiolibrary_Fluid_Examples_MeanRespiration.fmu
          - startTime: 0.000000
          - stopTime:  1800.000000
          - tolerance: 0.000001
          - stepSize:  0.720000
info:    model doesn't contain any continuous state
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_STDOUT        | warning | Non-Linear Solver try to handle a problem with a called assert.
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_STDOUT        | warning | While solving non-linear system an assertion failed during initialization.
|                 | |       | | The non-linear solver tries to solve the problem that could take some time.
|                 | |       | | It could help to provide better start-values for the iteration variables.
|                 | |       | | For more information simulate with -lv LOG_NLS_V
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.deadSpaceVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
LOG_ASSERT        | debug   | Division by zero (h - X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificEnthalpy(substanceData[$i1], 298.15, p, v, I) for $i1 in 1:size(substanceData, 1))) / (X * array(Physiolibrary.Fluid.Examples.MeanRespiration.alveolarVentilation.Medium.stateOfMatter.specificHeatCapacityCp(substanceData[$i1], 298.15, 1e5, 0.0, 0.0) for $i1 in 1:size(substanceData, 1))) in function context
info:    maximum step size for 'model.root': 0.720000
info:    Result file: model_res.mat (bufferSize=10)
info:    Final Statistics for 'model.root':
         NumSteps = 2503 NumRhsEvals  = 2504 NumLinSolvSetups = 128
         NumNonlinSolvIters = 2503 NumNonlinSolvConvFails = 0 NumErrTestFails = 0
info:    2 warnings
info:    0 errors