Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.conf.json
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo): time 0.0007016/0.0007016, allocations: 80.25 kB / 20.03 MB, free: 4.492 MB / 18.57 MB
"
[Timeout remaining time 180]
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo): time 0.000777/0.000777, allocations: 173.9 kB / 23.33 MB, free: 1.188 MB / 18.57 MB
"
[Timeout remaining time 180]
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo): time 0.8435/0.8435, allocations: 177.1 MB / 203.7 MB, free: 5.723 MB / 186.7 MB
"
[Timeout remaining time 179]
loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo", uses=false) [Timeout 180]
"Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo): time 0.6781/0.6781, allocations: 116 MB / 376.1 MB, free: 4.168 MB / 346.7 MB
"
[Timeout remaining time 179]
Using package ThermofluidStream with version 1.3.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ThermofluidStream main/package.mo)
Using package Modelica with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 4.1.0+maint.om/package.mo)
Using package Complex with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.1.0+maint.om/package.mo)
Using package ModelicaServices with version 4.1.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.1.0+maint.om/package.mo)
Running command: translateModel(ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance,tolerance=1e-06,outputFormat="mat",numberOfIntervals=100,variableFilter="CPUtime|EventCounter|Time|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.H0|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Hf|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.MM|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.R_s|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Tlimit|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.3.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.4.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.5.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.6.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.7.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.3.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.4.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.5.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.6.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.7.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.H0|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Hf|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.MM|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.R_s|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Tlimit|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.3.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.4.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.5.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.6.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.7.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.3.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.4.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.5.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.6.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.7.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow.2.|dropOfCommons.L|dropOfCommons.assertionLevel|dropOfCommons.g|dropOfCommons.instanceNameColor.1.|dropOfCommons.instanceNameColor.2.|dropOfCommons.instanceNameColor.3.|dropOfCommons.k_volume_damping|dropOfCommons.m_flow_reg|dropOfCommons.omega_reg|dropOfCommons.p_min|dropOfCommons.rho_min|firstOrder1.T|der.firstOrder1.y.|firstOrder1.initType|firstOrder1.k|firstOrder1.u|firstOrder1.y|firstOrder1.y_start|firstOrder2.T|der.firstOrder2.y.|firstOrder2.initType|firstOrder2.k|firstOrder2.u|firstOrder2.y|firstOrder2.y_start|firstOrder4.T|der.firstOrder4.y.|firstOrder4.initType|firstOrder4.k|firstOrder4.u|firstOrder4.y|firstOrder4.y_start|m_flow_pulse1.T_start|m_flow_pulse1.T_width|m_flow_pulse1.amplitude|m_flow_pulse1.count|m_flow_pulse1.nperiod|m_flow_pulse1.offset|m_flow_pulse1.period|m_flow_pulse1.startTime|m_flow_pulse1.width|m_flow_pulse1.y|m_flow_pulse2.T_start|m_flow_pulse2.T_width|m_flow_pulse2.amplitude|m_flow_pulse2.count|m_flow_pulse2.nperiod|m_flow_pulse2.offset|m_flow_pulse2.period|m_flow_pulse2.startTime|m_flow_pulse2.width|m_flow_pulse2.y|m_flow_pulse3.T_start|m_flow_pulse3.T_width|m_flow_pulse3.amplitude|m_flow_pulse3.count|m_flow_pulse3.nperiod|m_flow_pulse3.offset|m_flow_pulse3.period|m_flow_pulse3.startTime|m_flow_pulse3.width|m_flow_pulse3.y|m_flow_pulse4.T_start|m_flow_pulse4.T_width|m_flow_pulse4.amplitude|m_flow_pulse4.count|m_flow_pulse4.nperiod|m_flow_pulse4.offset|m_flow_pulse4.period|m_flow_pulse4.startTime|m_flow_pulse4.width|m_flow_pulse4.y|m_flow_pulse5.T_start|m_flow_pulse5.T_width|m_flow_pulse5.amplitude|m_flow_pulse5.count|m_flow_pulse5.nperiod|m_flow_pulse5.offset|m_flow_pulse5.period|m_flow_pulse5.startTime|m_flow_pulse5.width|m_flow_pulse5.y|m_flow_pulse6.T_start|m_flow_pulse6.T_width|m_flow_pulse6.amplitude|m_flow_pulse6.count|m_flow_pulse6.nperiod|m_flow_pulse6.offset|m_flow_pulse6.period|m_flow_pulse6.startTime|m_flow_pulse6.width|m_flow_pulse6.y|massFlowRateA1.L|massFlowRateA1.clip_p_out|massFlowRateA1.dp|massFlowRateA1.dr_corr|massFlowRateA1.h_in|massFlowRateA1.h_out|massFlowRateA1.initM_flow|der.massFlowRateA1.inlet.m_flow.|massFlowRateA1.inlet.m_flow|massFlowRateA1.inlet.r|massFlowRateA1.inlet.state.T|massFlowRateA1.inlet.state.p|massFlowRateA1.m_acceleration_0|massFlowRateA1.m_flow|massFlowRateA1.m_flowSpec|massFlowRateA1.m_flowStateSelect|massFlowRateA1.m_flow_0|massFlowRateA1.m_flow_actual|massFlowRateA1.m_flow_fixed|massFlowRateA1.m_flow_prescribed|massFlowRateA1.outlet.m_flow|massFlowRateA1.outlet.r|massFlowRateA1.outlet.state.T|massFlowRateA1.outlet.state.p|massFlowRateA1.p_in|massFlowRateA1.p_min|massFlowRateA1.p_out|massFlowRateA2.L|massFlowRateA2.clip_p_out|massFlowRateA2.dp|massFlowRateA2.dr_corr|massFlowRateA2.h_in|massFlowRateA2.h_out|massFlowRateA2.initM_flow|der.massFlowRateA2.inlet.m_flow.|massFlowRateA2.inlet.m_flow|massFlowRateA2.inlet.r|massFlowRateA2.inlet.state.T|massFlowRateA2.inlet.state.p|massFlowRateA2.m_acceleration_0|massFlowRateA2.m_flow|massFlowRateA2.m_flowSpec|massFlowRateA2.m_flowStateSelect|massFlowRateA2.m_flow_0|massFlowRateA2.m_flow_actual|massFlowRateA2.m_flow_fixed|massFlowRateA2.m_flow_prescribed|massFlowRateA2.outlet.m_flow|massFlowRateA2.outlet.r|massFlowRateA2.outlet.state.T|massFlowRateA2.outlet.state.p|massFlowRateA2.p_in|massFlowRateA2.p_min|massFlowRateA2.p_out|massFlowRateA3.L|massFlowRateA3.clip_p_out|massFlowRateA3.dp|massFlowRateA3.dr_corr|massFlowRateA3.h_in|massFlowRateA3.h_out|massFlowRateA3.initM_flow|der.massFlowRateA3.inlet.m_flow.|massFlowRateA3.inlet.m_flow|massFlowRateA3.inlet.r|massFlowRateA3.inlet.state.T|massFlowRateA3.inlet.state.p|massFlowRateA3.m_acceleration_0|massFlowRateA3.m_flow|massFlowRateA3.m_flowSpec|massFlowRateA3.m_flowStateSelect|massFlowRateA3.m_flow_0|massFlowRateA3.m_flow_actual|massFlowRateA3.m_flow_fixed|massFlowRateA3.m_flow_prescribed|massFlowRateA3.outlet.m_flow|massFlowRateA3.outlet.r|massFlowRateA3.outlet.state.T|massFlowRateA3.outlet.state.p|massFlowRateA3.p_in|massFlowRateA3.p_min|massFlowRateA3.p_out|massFlowRateB1.clip_p_out|massFlowRateB1.dp|massFlowRateB1.dr_corr|massFlowRateB1.h_in|massFlowRateB1.h_out|massFlowRateB1.initM_flow|massFlowRateB1.inlet.m_flow|massFlowRateB1.inlet.r|massFlowRateB1.inlet.state.T|massFlowRateB1.inlet.state.p|massFlowRateB1.m_acceleration_0|massFlowRateB1.m_flow|massFlowRateB1.m_flowSpec|massFlowRateB1.m_flowStateSelect|massFlowRateB1.m_flow_0|massFlowRateB1.m_flow_actual|massFlowRateB1.m_flow_fixed|massFlowRateB1.m_flow_prescribed|massFlowRateB1.outlet.m_flow|massFlowRateB1.outlet.r|massFlowRateB1.outlet.state.T|massFlowRateB1.outlet.state.p|massFlowRateB1.p_in|massFlowRateB1.p_min|massFlowRateB1.p_out|massFlowRateB2.clip_p_out|massFlowRateB2.dp|massFlowRateB2.dr_corr|massFlowRateB2.h_in|massFlowRateB2.h_out|massFlowRateB2.initM_flow|massFlowRateB2.inlet.m_flow|massFlowRateB2.inlet.r|massFlowRateB2.inlet.state.T|massFlowRateB2.inlet.state.p|massFlowRateB2.m_acceleration_0|massFlowRateB2.m_flow|massFlowRateB2.m_flowSpec|massFlowRateB2.m_flowStateSelect|massFlowRateB2.m_flow_0|massFlowRateB2.m_flow_actual|massFlowRateB2.m_flow_fixed|massFlowRateB2.m_flow_prescribed|massFlowRateB2.outlet.m_flow|massFlowRateB2.outlet.r|massFlowRateB2.outlet.state.T|massFlowRateB2.outlet.state.p|massFlowRateB2.p_in|massFlowRateB2.p_min|massFlowRateB2.p_out|massFlowRateB4.clip_p_out|massFlowRateB4.dp|massFlowRateB4.dr_corr|massFlowRateB4.h_in|massFlowRateB4.h_out|massFlowRateB4.initM_flow|massFlowRateB4.inlet.m_flow|massFlowRateB4.inlet.r|massFlowRateB4.inlet.state.T|massFlowRateB4.inlet.state.p|massFlowRateB4.m_acceleration_0|massFlowRateB4.m_flow|massFlowRateB4.m_flowSpec|massFlowRateB4.m_flowStateSelect|massFlowRateB4.m_flow_0|massFlowRateB4.m_flow_actual|massFlowRateB4.m_flow_fixed|massFlowRateB4.m_flow_prescribed|massFlowRateB4.outlet.m_flow|massFlowRateB4.outlet.r|massFlowRateB4.outlet.state.T|massFlowRateB4.outlet.state.p|massFlowRateB4.p_in|massFlowRateB4.p_min|massFlowRateB4.p_out|massFlowRateC4.L|massFlowRateC4.clip_p_out|massFlowRateC4.dp|massFlowRateC4.dr_corr|massFlowRateC4.h_in|massFlowRateC4.h_out|massFlowRateC4.initM_flow|der.massFlowRateC4.inlet.m_flow.|massFlowRateC4.inlet.m_flow|massFlowRateC4.inlet.r|massFlowRateC4.inlet.state.T|massFlowRateC4.inlet.state.p|massFlowRateC4.m_acceleration_0|massFlowRateC4.m_flow|massFlowRateC4.m_flowSpec|massFlowRateC4.m_flowStateSelect|massFlowRateC4.m_flow_0|massFlowRateC4.m_flow_actual|massFlowRateC4.m_flow_fixed|massFlowRateC4.m_flow_prescribed|massFlowRateC4.outlet.m_flow|massFlowRateC4.outlet.r|massFlowRateC4.outlet.state.T|massFlowRateC4.outlet.state.p|massFlowRateC4.p_in|massFlowRateC4.p_min|massFlowRateC4.p_out|massFlowRateRampC4.duration|massFlowRateRampC4.height|massFlowRateRampC4.offset|massFlowRateRampC4.startTime|massFlowRateRampC4.y|sinkA1.L|der.sinkA1.inlet.m_flow.|sinkA1.inlet.m_flow|sinkA1.inlet.r|sinkA1.inlet.state.T|sinkA1.inlet.state.p|sinkA2.L|der.sinkA2.inlet.m_flow.|sinkA2.inlet.m_flow|sinkA2.inlet.r|sinkA2.inlet.state.T|sinkA2.inlet.state.p|sinkA3.L|der.sinkA3.inlet.m_flow.|sinkA3.inlet.m_flow|sinkA3.inlet.r|sinkA3.inlet.state.T|sinkA3.inlet.state.p|sinkB1.inlet.m_flow|sinkB1.inlet.r|sinkB1.inlet.state.T|sinkB1.inlet.state.p|sinkB2.inlet.m_flow|sinkB2.inlet.r|sinkB2.inlet.state.T|sinkB2.inlet.state.p|sinkB3.inlet.m_flow|sinkB3.inlet.r|sinkB3.inlet.state.T|sinkB3.inlet.state.p|sinkC4.L|der.sinkC4.inlet.m_flow.|sinkC4.inlet.m_flow|sinkC4.inlet.r|sinkC4.inlet.state.T|sinkC4.inlet.state.p|source1.T0|source1.T0_par|source1.h0|source1.h0_par|source1.outlet.m_flow|source1.outlet.r|source1.outlet.state.T|source1.outlet.state.p|source1.p0|source1.p0_par|source2.T0|source2.T0_par|source2.h0|source2.h0_par|source2.outlet.m_flow|source2.outlet.r|source2.outlet.state.T|source2.outlet.state.p|source2.p0|source2.p0_par|source3.T0|source3.T0_par|source3.h0|source3.h0_par|source3.outlet.m_flow|source3.outlet.r|source3.outlet.state.T|source3.outlet.state.p|source3.p0|source3.p0_par|splitter1.inlet.m_flow|splitter1.inlet.r|splitter1.inlet.state.T|splitter1.inlet.state.p|splitter1.outletA.m_flow|splitter1.outletA.r|splitter1.outletA.state.T|splitter1.outletA.state.p|splitter1.outletB.m_flow|splitter1.outletB.r|splitter1.outletB.state.T|splitter1.outletB.state.p|splitter1.splitterN.N|splitter1.splitterN.inlet.m_flow|splitter1.splitterN.inlet.r|splitter1.splitterN.inlet.state.T|splitter1.splitterN.inlet.state.p|splitter1.splitterN.outlets.1..m_flow|splitter1.splitterN.outlets.1..r|splitter1.splitterN.outlets.1..state.T|splitter1.splitterN.outlets.1..state.p|splitter1.splitterN.outlets.2..m_flow|splitter1.splitterN.outlets.2..r|splitter1.splitterN.outlets.2..state.T|splitter1.splitterN.outlets.2..state.p|splitter1.splitterN.r_mix|splitter4.inlet.m_flow|splitter4.inlet.r|splitter4.inlet.state.T|splitter4.inlet.state.p|splitter4.outletA.m_flow|splitter4.outletA.r|splitter4.outletA.state.T|splitter4.outletA.state.p|splitter4.outletB.m_flow|splitter4.outletB.r|splitter4.outletB.state.T|splitter4.outletB.state.p|splitter4.splitterN.N|splitter4.splitterN.inlet.m_flow|splitter4.splitterN.inlet.r|splitter4.splitterN.inlet.state.T|splitter4.splitterN.inlet.state.p|splitter4.splitterN.outlets.1..m_flow|splitter4.splitterN.outlets.1..r|splitter4.splitterN.outlets.1..state.T|splitter4.splitterN.outlets.1..state.p|splitter4.splitterN.outlets.2..m_flow|splitter4.splitterN.outlets.2..r|splitter4.splitterN.outlets.2..state.T|splitter4.splitterN.outlets.2..state.p|splitter4.splitterN.r_mix|splitterX1.inlet.m_flow|splitterX1.inlet.r|splitterX1.inlet.state.T|splitterX1.inlet.state.p|splitterX1.outletA.m_flow|splitterX1.outletA.r|splitterX1.outletA.state.T|splitterX1.outletA.state.p|splitterX1.outletB.m_flow|splitterX1.outletB.r|splitterX1.outletB.state.T|splitterX1.outletB.state.p|splitterX1.outletC.m_flow|splitterX1.outletC.r|splitterX1.outletC.state.T|splitterX1.outletC.state.p|splitterX1.splitterN.N|splitterX1.splitterN.inlet.m_flow|splitterX1.splitterN.inlet.r|splitterX1.splitterN.inlet.state.T|splitterX1.splitterN.inlet.state.p|splitterX1.splitterN.outlets.1..m_flow|splitterX1.splitterN.outlets.1..r|splitterX1.splitterN.outlets.1..state.T|splitterX1.splitterN.outlets.1..state.p|splitterX1.splitterN.outlets.2..m_flow|splitterX1.splitterN.outlets.2..r|splitterX1.splitterN.outlets.2..state.T|splitterX1.splitterN.outlets.2..state.p|splitterX1.splitterN.outlets.3..m_flow|splitterX1.splitterN.outlets.3..r|splitterX1.splitterN.outlets.3..state.T|splitterX1.splitterN.outlets.3..state.p|splitterX1.splitterN.r_mix",fileNamePrefix="ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance")
translateModel(ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance,tolerance=1e-06,outputFormat="mat",numberOfIntervals=100,variableFilter="CPUtime|EventCounter|Time|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.H0|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Hf|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.MM|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.R_s|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Tlimit|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.3.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.4.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.5.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.6.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh.7.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.3.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.4.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.5.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.6.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow.7.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.H0|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Hf|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.MM|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.R_s|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Tlimit|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.3.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.4.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.5.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.6.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh.7.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.3.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.4.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.5.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.6.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow.7.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh.2.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow.1.|_GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow.2.|dropOfCommons.L|dropOfCommons.assertionLevel|dropOfCommons.g|dropOfCommons.instanceNameColor.1.|dropOfCommons.instanceNameColor.2.|dropOfCommons.instanceNameColor.3.|dropOfCommons.k_volume_damping|dropOfCommons.m_flow_reg|dropOfCommons.omega_reg|dropOfCommons.p_min|dropOfCommons.rho_min|firstOrder1.T|der.firstOrder1.y.|firstOrder1.initType|firstOrder1.k|firstOrder1.u|firstOrder1.y|firstOrder1.y_start|firstOrder2.T|der.firstOrder2.y.|firstOrder2.initType|firstOrder2.k|firstOrder2.u|firstOrder2.y|firstOrder2.y_start|firstOrder4.T|der.firstOrder4.y.|firstOrder4.initType|firstOrder4.k|firstOrder4.u|firstOrder4.y|firstOrder4.y_start|m_flow_pulse1.T_start|m_flow_pulse1.T_width|m_flow_pulse1.amplitude|m_flow_pulse1.count|m_flow_pulse1.nperiod|m_flow_pulse1.offset|m_flow_pulse1.period|m_flow_pulse1.startTime|m_flow_pulse1.width|m_flow_pulse1.y|m_flow_pulse2.T_start|m_flow_pulse2.T_width|m_flow_pulse2.amplitude|m_flow_pulse2.count|m_flow_pulse2.nperiod|m_flow_pulse2.offset|m_flow_pulse2.period|m_flow_pulse2.startTime|m_flow_pulse2.width|m_flow_pulse2.y|m_flow_pulse3.T_start|m_flow_pulse3.T_width|m_flow_pulse3.amplitude|m_flow_pulse3.count|m_flow_pulse3.nperiod|m_flow_pulse3.offset|m_flow_pulse3.period|m_flow_pulse3.startTime|m_flow_pulse3.width|m_flow_pulse3.y|m_flow_pulse4.T_start|m_flow_pulse4.T_width|m_flow_pulse4.amplitude|m_flow_pulse4.count|m_flow_pulse4.nperiod|m_flow_pulse4.offset|m_flow_pulse4.period|m_flow_pulse4.startTime|m_flow_pulse4.width|m_flow_pulse4.y|m_flow_pulse5.T_start|m_flow_pulse5.T_width|m_flow_pulse5.amplitude|m_flow_pulse5.count|m_flow_pulse5.nperiod|m_flow_pulse5.offset|m_flow_pulse5.period|m_flow_pulse5.startTime|m_flow_pulse5.width|m_flow_pulse5.y|m_flow_pulse6.T_start|m_flow_pulse6.T_width|m_flow_pulse6.amplitude|m_flow_pulse6.count|m_flow_pulse6.nperiod|m_flow_pulse6.offset|m_flow_pulse6.period|m_flow_pulse6.startTime|m_flow_pulse6.width|m_flow_pulse6.y|massFlowRateA1.L|massFlowRateA1.clip_p_out|massFlowRateA1.dp|massFlowRateA1.dr_corr|massFlowRateA1.h_in|massFlowRateA1.h_out|massFlowRateA1.initM_flow|der.massFlowRateA1.inlet.m_flow.|massFlowRateA1.inlet.m_flow|massFlowRateA1.inlet.r|massFlowRateA1.inlet.state.T|massFlowRateA1.inlet.state.p|massFlowRateA1.m_acceleration_0|massFlowRateA1.m_flow|massFlowRateA1.m_flowSpec|massFlowRateA1.m_flowStateSelect|massFlowRateA1.m_flow_0|massFlowRateA1.m_flow_actual|massFlowRateA1.m_flow_fixed|massFlowRateA1.m_flow_prescribed|massFlowRateA1.outlet.m_flow|massFlowRateA1.outlet.r|massFlowRateA1.outlet.state.T|massFlowRateA1.outlet.state.p|massFlowRateA1.p_in|massFlowRateA1.p_min|massFlowRateA1.p_out|massFlowRateA2.L|massFlowRateA2.clip_p_out|massFlowRateA2.dp|massFlowRateA2.dr_corr|massFlowRateA2.h_in|massFlowRateA2.h_out|massFlowRateA2.initM_flow|der.massFlowRateA2.inlet.m_flow.|massFlowRateA2.inlet.m_flow|massFlowRateA2.inlet.r|massFlowRateA2.inlet.state.T|massFlowRateA2.inlet.state.p|massFlowRateA2.m_acceleration_0|massFlowRateA2.m_flow|massFlowRateA2.m_flowSpec|massFlowRateA2.m_flowStateSelect|massFlowRateA2.m_flow_0|massFlowRateA2.m_flow_actual|massFlowRateA2.m_flow_fixed|massFlowRateA2.m_flow_prescribed|massFlowRateA2.outlet.m_flow|massFlowRateA2.outlet.r|massFlowRateA2.outlet.state.T|massFlowRateA2.outlet.state.p|massFlowRateA2.p_in|massFlowRateA2.p_min|massFlowRateA2.p_out|massFlowRateA3.L|massFlowRateA3.clip_p_out|massFlowRateA3.dp|massFlowRateA3.dr_corr|massFlowRateA3.h_in|massFlowRateA3.h_out|massFlowRateA3.initM_flow|der.massFlowRateA3.inlet.m_flow.|massFlowRateA3.inlet.m_flow|massFlowRateA3.inlet.r|massFlowRateA3.inlet.state.T|massFlowRateA3.inlet.state.p|massFlowRateA3.m_acceleration_0|massFlowRateA3.m_flow|massFlowRateA3.m_flowSpec|massFlowRateA3.m_flowStateSelect|massFlowRateA3.m_flow_0|massFlowRateA3.m_flow_actual|massFlowRateA3.m_flow_fixed|massFlowRateA3.m_flow_prescribed|massFlowRateA3.outlet.m_flow|massFlowRateA3.outlet.r|massFlowRateA3.outlet.state.T|massFlowRateA3.outlet.state.p|massFlowRateA3.p_in|massFlowRateA3.p_min|massFlowRateA3.p_out|massFlowRateB1.clip_p_out|massFlowRateB1.dp|massFlowRateB1.dr_corr|massFlowRateB1.h_in|massFlowRateB1.h_out|massFlowRateB1.initM_flow|massFlowRateB1.inlet.m_flow|massFlowRateB1.inlet.r|massFlowRateB1.inlet.state.T|massFlowRateB1.inlet.state.p|massFlowRateB1.m_acceleration_0|massFlowRateB1.m_flow|massFlowRateB1.m_flowSpec|massFlowRateB1.m_flowStateSelect|massFlowRateB1.m_flow_0|massFlowRateB1.m_flow_actual|massFlowRateB1.m_flow_fixed|massFlowRateB1.m_flow_prescribed|massFlowRateB1.outlet.m_flow|massFlowRateB1.outlet.r|massFlowRateB1.outlet.state.T|massFlowRateB1.outlet.state.p|massFlowRateB1.p_in|massFlowRateB1.p_min|massFlowRateB1.p_out|massFlowRateB2.clip_p_out|massFlowRateB2.dp|massFlowRateB2.dr_corr|massFlowRateB2.h_in|massFlowRateB2.h_out|massFlowRateB2.initM_flow|massFlowRateB2.inlet.m_flow|massFlowRateB2.inlet.r|massFlowRateB2.inlet.state.T|massFlowRateB2.inlet.state.p|massFlowRateB2.m_acceleration_0|massFlowRateB2.m_flow|massFlowRateB2.m_flowSpec|massFlowRateB2.m_flowStateSelect|massFlowRateB2.m_flow_0|massFlowRateB2.m_flow_actual|massFlowRateB2.m_flow_fixed|massFlowRateB2.m_flow_prescribed|massFlowRateB2.outlet.m_flow|massFlowRateB2.outlet.r|massFlowRateB2.outlet.state.T|massFlowRateB2.outlet.state.p|massFlowRateB2.p_in|massFlowRateB2.p_min|massFlowRateB2.p_out|massFlowRateB4.clip_p_out|massFlowRateB4.dp|massFlowRateB4.dr_corr|massFlowRateB4.h_in|massFlowRateB4.h_out|massFlowRateB4.initM_flow|massFlowRateB4.inlet.m_flow|massFlowRateB4.inlet.r|massFlowRateB4.inlet.state.T|massFlowRateB4.inlet.state.p|massFlowRateB4.m_acceleration_0|massFlowRateB4.m_flow|massFlowRateB4.m_flowSpec|massFlowRateB4.m_flowStateSelect|massFlowRateB4.m_flow_0|massFlowRateB4.m_flow_actual|massFlowRateB4.m_flow_fixed|massFlowRateB4.m_flow_prescribed|massFlowRateB4.outlet.m_flow|massFlowRateB4.outlet.r|massFlowRateB4.outlet.state.T|massFlowRateB4.outlet.state.p|massFlowRateB4.p_in|massFlowRateB4.p_min|massFlowRateB4.p_out|massFlowRateC4.L|massFlowRateC4.clip_p_out|massFlowRateC4.dp|massFlowRateC4.dr_corr|massFlowRateC4.h_in|massFlowRateC4.h_out|massFlowRateC4.initM_flow|der.massFlowRateC4.inlet.m_flow.|massFlowRateC4.inlet.m_flow|massFlowRateC4.inlet.r|massFlowRateC4.inlet.state.T|massFlowRateC4.inlet.state.p|massFlowRateC4.m_acceleration_0|massFlowRateC4.m_flow|massFlowRateC4.m_flowSpec|massFlowRateC4.m_flowStateSelect|massFlowRateC4.m_flow_0|massFlowRateC4.m_flow_actual|massFlowRateC4.m_flow_fixed|massFlowRateC4.m_flow_prescribed|massFlowRateC4.outlet.m_flow|massFlowRateC4.outlet.r|massFlowRateC4.outlet.state.T|massFlowRateC4.outlet.state.p|massFlowRateC4.p_in|massFlowRateC4.p_min|massFlowRateC4.p_out|massFlowRateRampC4.duration|massFlowRateRampC4.height|massFlowRateRampC4.offset|massFlowRateRampC4.startTime|massFlowRateRampC4.y|sinkA1.L|der.sinkA1.inlet.m_flow.|sinkA1.inlet.m_flow|sinkA1.inlet.r|sinkA1.inlet.state.T|sinkA1.inlet.state.p|sinkA2.L|der.sinkA2.inlet.m_flow.|sinkA2.inlet.m_flow|sinkA2.inlet.r|sinkA2.inlet.state.T|sinkA2.inlet.state.p|sinkA3.L|der.sinkA3.inlet.m_flow.|sinkA3.inlet.m_flow|sinkA3.inlet.r|sinkA3.inlet.state.T|sinkA3.inlet.state.p|sinkB1.inlet.m_flow|sinkB1.inlet.r|sinkB1.inlet.state.T|sinkB1.inlet.state.p|sinkB2.inlet.m_flow|sinkB2.inlet.r|sinkB2.inlet.state.T|sinkB2.inlet.state.p|sinkB3.inlet.m_flow|sinkB3.inlet.r|sinkB3.inlet.state.T|sinkB3.inlet.state.p|sinkC4.L|der.sinkC4.inlet.m_flow.|sinkC4.inlet.m_flow|sinkC4.inlet.r|sinkC4.inlet.state.T|sinkC4.inlet.state.p|source1.T0|source1.T0_par|source1.h0|source1.h0_par|source1.outlet.m_flow|source1.outlet.r|source1.outlet.state.T|source1.outlet.state.p|source1.p0|source1.p0_par|source2.T0|source2.T0_par|source2.h0|source2.h0_par|source2.outlet.m_flow|source2.outlet.r|source2.outlet.state.T|source2.outlet.state.p|source2.p0|source2.p0_par|source3.T0|source3.T0_par|source3.h0|source3.h0_par|source3.outlet.m_flow|source3.outlet.r|source3.outlet.state.T|source3.outlet.state.p|source3.p0|source3.p0_par|splitter1.inlet.m_flow|splitter1.inlet.r|splitter1.inlet.state.T|splitter1.inlet.state.p|splitter1.outletA.m_flow|splitter1.outletA.r|splitter1.outletA.state.T|splitter1.outletA.state.p|splitter1.outletB.m_flow|splitter1.outletB.r|splitter1.outletB.state.T|splitter1.outletB.state.p|splitter1.splitterN.N|splitter1.splitterN.inlet.m_flow|splitter1.splitterN.inlet.r|splitter1.splitterN.inlet.state.T|splitter1.splitterN.inlet.state.p|splitter1.splitterN.outlets.1..m_flow|splitter1.splitterN.outlets.1..r|splitter1.splitterN.outlets.1..state.T|splitter1.splitterN.outlets.1..state.p|splitter1.splitterN.outlets.2..m_flow|splitter1.splitterN.outlets.2..r|splitter1.splitterN.outlets.2..state.T|splitter1.splitterN.outlets.2..state.p|splitter1.splitterN.r_mix|splitter4.inlet.m_flow|splitter4.inlet.r|splitter4.inlet.state.T|splitter4.inlet.state.p|splitter4.outletA.m_flow|splitter4.outletA.r|splitter4.outletA.state.T|splitter4.outletA.state.p|splitter4.outletB.m_flow|splitter4.outletB.r|splitter4.outletB.state.T|splitter4.outletB.state.p|splitter4.splitterN.N|splitter4.splitterN.inlet.m_flow|splitter4.splitterN.inlet.r|splitter4.splitterN.inlet.state.T|splitter4.splitterN.inlet.state.p|splitter4.splitterN.outlets.1..m_flow|splitter4.splitterN.outlets.1..r|splitter4.splitterN.outlets.1..state.T|splitter4.splitterN.outlets.1..state.p|splitter4.splitterN.outlets.2..m_flow|splitter4.splitterN.outlets.2..r|splitter4.splitterN.outlets.2..state.T|splitter4.splitterN.outlets.2..state.p|splitter4.splitterN.r_mix|splitterX1.inlet.m_flow|splitterX1.inlet.r|splitterX1.inlet.state.T|splitterX1.inlet.state.p|splitterX1.outletA.m_flow|splitterX1.outletA.r|splitterX1.outletA.state.T|splitterX1.outletA.state.p|splitterX1.outletB.m_flow|splitterX1.outletB.r|splitterX1.outletB.state.T|splitterX1.outletB.state.p|splitterX1.outletC.m_flow|splitterX1.outletC.r|splitterX1.outletC.state.T|splitterX1.outletC.state.p|splitterX1.splitterN.N|splitterX1.splitterN.inlet.m_flow|splitterX1.splitterN.inlet.r|splitterX1.splitterN.inlet.state.T|splitterX1.splitterN.inlet.state.p|splitterX1.splitterN.outlets.1..m_flow|splitterX1.splitterN.outlets.1..r|splitterX1.splitterN.outlets.1..state.T|splitterX1.splitterN.outlets.1..state.p|splitterX1.splitterN.outlets.2..m_flow|splitterX1.splitterN.outlets.2..r|splitterX1.splitterN.outlets.2..state.T|splitterX1.splitterN.outlets.2..state.p|splitterX1.splitterN.outlets.3..m_flow|splitterX1.splitterN.outlets.3..r|splitterX1.splitterN.outlets.3..state.T|splitterX1.splitterN.outlets.3..state.p|splitterX1.splitterN.r_mix",fileNamePrefix="ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance") [Timeout 660]
"Notification: Performance of FrontEnd - loaded program: time 2.023e-06/2.023e-06, allocations: 0 / 0.5548 GB, free: 12.64 MB / 490.7 MB
Notification: Performance of FrontEnd - Absyn->SCode: time 4.203e-05/4.405e-05, allocations: 5.828 kB / 0.5548 GB, free: 12.64 MB / 490.7 MB
Notification: Performance of NFInst.instantiate(ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance): time 0.555/0.5551, allocations: 230 MB / 0.7794 GB, free: 7.199 MB / 0.6198 GB
Notification: Performance of NFInst.instExpressions: time 0.005127/0.5602, allocations: 2.893 MB / 0.7822 GB, free: 4.297 MB / 0.6198 GB
Notification: Performance of NFInst.updateImplicitVariability: time 0.001594/0.5618, allocations: 91.12 kB / 0.7823 GB, free: 4.207 MB / 0.6198 GB
Notification: Performance of NFTyping.typeComponents: time 0.002266/0.5641, allocations: 0.8299 MB / 0.7831 GB, free: 3.371 MB / 0.6198 GB
Notification: Performance of NFTyping.typeBindings: time 0.003808/0.5679, allocations: 1.451 MB / 0.7845 GB, free: 1.91 MB / 0.6198 GB
Notification: Performance of NFTyping.typeClassSections: time 0.003488/0.5714, allocations: 1.467 MB / 0.786 GB, free: 448 kB / 0.6198 GB
Notification: Performance of NFFlatten.flatten: time 0.003254/0.5746, allocations: 2.45 MB / 0.7883 GB, free: 13.98 MB / 0.6355 GB
Notification: Performance of NFFlatten.resolveConnections: time 0.001048/0.5757, allocations: 389.4 kB / 0.7887 GB, free: 13.56 MB / 0.6355 GB
Notification: Performance of NFEvalConstants.evaluate: time 0.003397/0.5791, allocations: 1.733 MB / 0.7904 GB, free: 11.82 MB / 0.6355 GB
Notification: Performance of NFSimplifyModel.simplify: time 0.001072/0.5801, allocations: 0.6386 MB / 0.791 GB, free: 11.18 MB / 0.6355 GB
Notification: Performance of NFPackage.collectConstants: time 0.0002678/0.5804, allocations: 128 kB / 0.7912 GB, free: 11.06 MB / 0.6355 GB
Notification: Performance of NFFlatten.collectFunctions: time 0.002669/0.5831, allocations: 1.178 MB / 0.7923 GB, free: 9.879 MB / 0.6355 GB
Notification: Performance of NFScalarize.scalarize: time 0.0002755/0.5833, allocations: 306.6 kB / 0.7926 GB, free: 9.578 MB / 0.6355 GB
Notification: Performance of NFVerifyModel.verify: time 0.0007063/0.5841, allocations: 0.5416 MB / 0.7931 GB, free: 9.035 MB / 0.6355 GB
Notification: Performance of NFConvertDAE.convert: time 0.004767/0.5888, allocations: 2.672 MB / 0.7957 GB, free: 6.355 MB / 0.6355 GB
Notification: Performance of FrontEnd - DAE generated: time 4.579e-06/0.5888, allocations: 0 / 0.7957 GB, free: 6.355 MB / 0.6355 GB
Notification: Performance of FrontEnd: time 1.463e-06/0.5888, allocations: 0 / 0.7957 GB, free: 6.355 MB / 0.6355 GB
Notification: Performance of Transformations before backend: time 7.841e-05/0.5889, allocations: 0 / 0.7957 GB, free: 6.355 MB / 0.6355 GB
Notification: Model statistics after passing the front-end and creating the data structures used by the back-end:
 * Number of equations: 289
 * Number of variables: 289
Notification: Performance of Generate backend data structure: time 0.003947/0.5929, allocations: 2.263 MB / 0.7979 GB, free: 4.012 MB / 0.6355 GB
Notification: Performance of prepare preOptimizeDAE: time 4.8e-05/0.5929, allocations: 11.97 kB / 0.798 GB, free: 4 MB / 0.6355 GB
Notification: Performance of preOpt normalInlineFunction (simulation): time 0.0005977/0.5935, allocations: 234.7 kB / 0.7982 GB, free: 3.77 MB / 0.6355 GB
Notification: Performance of preOpt evaluateParameters (simulation): time 0.001486/0.595, allocations: 1.033 MB / 0.7992 GB, free: 2.688 MB / 0.6355 GB
Notification: Performance of preOpt simplifyIfEquations (simulation): time 6.193e-05/0.595, allocations: 94.25 kB / 0.7993 GB, free: 2.594 MB / 0.6355 GB
Notification: Performance of preOpt expandDerOperator (simulation): time 0.0001446/0.5952, allocations: 123.9 kB / 0.7994 GB, free: 2.473 MB / 0.6355 GB
Notification: Performance of preOpt clockPartitioning (simulation): time 0.001836/0.597, allocations: 1.256 MB / 0.8006 GB, free: 1.156 MB / 0.6355 GB
Notification: Performance of preOpt findStateOrder (simulation): time 2.542e-05/0.5971, allocations: 4 kB / 0.8006 GB, free: 1.152 MB / 0.6355 GB
Notification: Performance of preOpt replaceEdgeChange (simulation): time 7.822e-05/0.5971, allocations: 47.98 kB / 0.8007 GB, free: 1.105 MB / 0.6355 GB
Notification: Performance of preOpt inlineArrayEqn (simulation): time 2.022e-05/0.5971, allocations: 28 kB / 0.8007 GB, free: 1.078 MB / 0.6355 GB
Notification: Performance of preOpt removeEqualRHS (simulation): time 0.00149/0.5986, allocations: 0.9067 MB / 0.8016 GB, free: 176 kB / 0.6355 GB
Notification: Performance of preOpt removeSimpleEquations (simulation): time 0.005731/0.6044, allocations: 3.149 MB / 0.8047 GB, free: 12.96 MB / 0.6511 GB
Notification: Performance of preOpt comSubExp (simulation): time 0.001206/0.6056, allocations: 0.5973 MB / 0.8052 GB, free: 12.31 MB / 0.6511 GB
Notification: Performance of preOpt resolveLoops (simulation): time 0.0004586/0.606, allocations: 273 kB / 0.8055 GB, free: 12.02 MB / 0.6511 GB
Notification: Performance of preOpt evalFunc (simulation): time 0.0001194/0.6062, allocations: 19.98 kB / 0.8055 GB, free: 12 MB / 0.6511 GB
Notification: Performance of preOpt encapsulateWhenConditions (simulation): time 0.0007216/0.6069, allocations: 0.531 MB / 0.806 GB, free: 11.43 MB / 0.6511 GB
Notification: Performance of pre-optimization done (n=53): time 4.549e-06/0.6069, allocations: 0 / 0.806 GB, free: 11.43 MB / 0.6511 GB
Notification: Performance of matching and sorting (n=54): time 0.005137/0.612, allocations: 3.708 MB / 0.8097 GB, free: 7.664 MB / 0.6511 GB
Notification: Performance of inlineWhenForInitialization (initialization): time 0.0001256/0.6121, allocations: 306.6 kB / 0.81 GB, free: 7.297 MB / 0.6511 GB
Notification: Performance of selectInitializationVariablesDAE (initialization): time 0.0008998/0.613, allocations: 0.899 MB / 0.8108 GB, free: 6.383 MB / 0.6511 GB
Notification: Performance of collectPreVariables (initialization): time 0.0001121/0.6132, allocations: 45.7 kB / 0.8109 GB, free: 6.332 MB / 0.6511 GB
Notification: Performance of collectInitialEqns (initialization): time 0.0004766/0.6136, allocations: 0.7305 MB / 0.8116 GB, free: 5.594 MB / 0.6511 GB
Notification: Performance of collectInitialBindings (initialization): time 0.0001808/0.6138, allocations: 186.5 kB / 0.8118 GB, free: 5.41 MB / 0.6511 GB
Notification: Performance of simplifyInitialFunctions (initialization): time 0.0002096/0.614, allocations: 190.8 kB / 0.8119 GB, free: 5.219 MB / 0.6511 GB
Notification: Performance of setup shared object (initialization): time 0.0001084/0.6141, allocations: 337.9 kB / 0.8123 GB, free: 4.883 MB / 0.6511 GB
Notification: Performance of preBalanceInitialSystem (initialization): time 0.0006711/0.6148, allocations: 476 kB / 0.8127 GB, free: 4.383 MB / 0.6511 GB
Notification: Performance of partitionIndependentBlocks (initialization): time 0.0006859/0.6155, allocations: 0.6566 MB / 0.8134 GB, free: 3.613 MB / 0.6511 GB
Notification: Performance of analyzeInitialSystem (initialization): time 0.001131/0.6166, allocations: 0.9122 MB / 0.8143 GB, free: 2.598 MB / 0.6511 GB
Notification: Performance of solveInitialSystemEqSystem (initialization): time 9.298e-06/0.6166, allocations: 0 / 0.8143 GB, free: 2.598 MB / 0.6511 GB
Notification: Performance of matching and sorting (n=99) (initialization): time 0.001814/0.6184, allocations: 1.364 MB / 0.8156 GB, free: 1.152 MB / 0.6511 GB
Notification: Performance of prepare postOptimizeDAE: time 9.978e-05/0.6185, allocations: 182.2 kB / 0.8158 GB, free: 0.9375 MB / 0.6511 GB
Notification: Performance of postOpt simplifyComplexFunction (initialization): time 1.37e-05/0.6186, allocations: 4 kB / 0.8158 GB, free: 0.9336 MB / 0.6511 GB
Notification: Performance of postOpt tearingSystem (initialization): time 3.019e-05/0.6186, allocations: 12.28 kB / 0.8158 GB, free: 0.9219 MB / 0.6511 GB
Notification: Performance of postOpt solveSimpleEquations (initialization): time 0.0004527/0.619, allocations: 219.7 kB / 0.816 GB, free: 0.707 MB / 0.6511 GB
Notification: Performance of postOpt calculateStrongComponentJacobians (initialization): time 1.414e-05/0.6191, allocations: 15.94 kB / 0.816 GB, free: 0.6914 MB / 0.6511 GB
Notification: Performance of postOpt simplifyAllExpressions (initialization): time 0.0006262/0.6197, allocations: 111.7 kB / 0.8161 GB, free: 0.582 MB / 0.6511 GB
Notification: Performance of postOpt collapseArrayExpressions (initialization): time 0.0001176/0.6198, allocations: 84.86 kB / 0.8162 GB, free: 0.5 MB / 0.6511 GB
Notification: Model statistics after passing the back-end for initialization:
 * Number of independent subsystems: 24
 * Number of states: 0 ()
 * Number of discrete variables: 30 (m_flow_pulse4.count,$PRE.m_flow_pulse4.count,m_flow_pulse4.T_start,$PRE.m_flow_pulse4.T_start,m_flow_pulse3.count,$PRE.m_flow_pulse3.count,m_flow_pulse3.T_start,$PRE.m_flow_pulse3.T_start,$whenCondition5,$whenCondition6,m_flow_pulse2.count,$PRE.m_flow_pulse2.count,m_flow_pulse2.T_start,$PRE.m_flow_pulse2.T_start,m_flow_pulse1.count,$PRE.m_flow_pulse1.count,m_flow_pulse1.T_start,$PRE.m_flow_pulse1.T_start,$whenCondition3,$whenCondition4,m_flow_pulse6.count,$PRE.m_flow_pulse6.count,m_flow_pulse6.T_start,$PRE.m_flow_pulse6.T_start,m_flow_pulse5.count,$PRE.m_flow_pulse5.count,m_flow_pulse5.T_start,$PRE.m_flow_pulse5.T_start,$whenCondition1,$whenCondition2)
 * Number of discrete states: 0 ()
 * Number of clocked states: 0 ()
 * Top-level inputs: 0
Notification: Strong component statistics for initialization (93):
 * Single equations (assignments): 87
 * Array equations: 0
 * Algorithm blocks: 6
 * Record equations: 0
 * When equations: 0
 * If-equations: 0
 * Equation systems (not torn): 0
 * Torn equation systems: 0
 * Mixed (continuous/discrete) equation systems: 0
Notification: Performance of prepare postOptimizeDAE: time 0.0008493/0.6206, allocations: 293.5 kB / 0.8165 GB, free: 212 kB / 0.6511 GB
Notification: Performance of postOpt lateInlineFunction (simulation): time 0.0001944/0.6208, allocations: 119.2 kB / 0.8166 GB, free: 92 kB / 0.6511 GB
Notification: Performance of postOpt wrapFunctionCalls (simulation): time 0.001337/0.6222, allocations: 1.278 MB / 0.8178 GB, free: 14.79 MB / 0.6667 GB
Notification: Performance of postOpt inlineArrayEqn (simulation): time 7.865e-06/0.6222, allocations: 8.219 kB / 0.8178 GB, free: 14.78 MB / 0.6667 GB
Notification: Performance of postOpt constantLinearSystem (simulation): time 1.129e-05/0.6222, allocations: 4 kB / 0.8178 GB, free: 14.77 MB / 0.6667 GB
Notification: Performance of postOpt simplifysemiLinear (simulation): time 1.159e-05/0.6222, allocations: 4 kB / 0.8178 GB, free: 14.77 MB / 0.6667 GB
Notification: Performance of postOpt removeSimpleEquations (simulation): time 0.001672/0.6239, allocations: 1.505 MB / 0.8193 GB, free: 13.21 MB / 0.6667 GB
Notification: Performance of postOpt simplifyComplexFunction (simulation): time 9.047e-06/0.6239, allocations: 8.812 kB / 0.8193 GB, free: 13.2 MB / 0.6667 GB
Notification: Performance of postOpt solveSimpleEquations (simulation): time 0.0003722/0.6243, allocations: 136 kB / 0.8195 GB, free: 13.07 MB / 0.6667 GB
Notification: Performance of postOpt tearingSystem (simulation): time 8.516e-06/0.6243, allocations: 4 kB / 0.8195 GB, free: 13.06 MB / 0.6667 GB
Notification: Performance of postOpt inputDerivativesUsed (simulation): time 5.031e-05/0.6243, allocations: 27.97 kB / 0.8195 GB, free: 13.04 MB / 0.6667 GB
Notification: Performance of postOpt calculateStrongComponentJacobians (simulation): time 7.264e-06/0.6243, allocations: 7.938 kB / 0.8195 GB, free: 13.03 MB / 0.6667 GB
Notification: Performance of postOpt calculateStateSetsJacobians (simulation): time 3.266e-06/0.6243, allocations: 4 kB / 0.8195 GB, free: 13.02 MB / 0.6667 GB
Notification: Performance of postOpt symbolicJacobian (simulation): time 0.001714/0.626, allocations: 1.056 MB / 0.8205 GB, free: 11.92 MB / 0.6667 GB
Notification: Performance of postOpt removeConstants (simulation): time 0.0002743/0.6263, allocations: 142.9 kB / 0.8207 GB, free: 11.79 MB / 0.6667 GB
Notification: Performance of postOpt simplifyTimeIndepFuncCalls (simulation): time 0.000113/0.6264, allocations: 19.95 kB / 0.8207 GB, free: 11.77 MB / 0.6667 GB
Notification: Performance of postOpt simplifyAllExpressions (simulation): time 0.0003448/0.6268, allocations: 87.81 kB / 0.8208 GB, free: 11.68 MB / 0.6667 GB
Notification: Performance of postOpt findZeroCrossings (simulation): time 0.0001804/0.627, allocations: 95.8 kB / 0.8209 GB, free: 11.59 MB / 0.6667 GB
Notification: Performance of postOpt collapseArrayExpressions (simulation): time 5.929e-05/0.627, allocations: 43.98 kB / 0.8209 GB, free: 11.54 MB / 0.6667 GB
Notification: Performance of sorting global known variables: time 0.0006624/0.6277, allocations: 0.6145 MB / 0.8215 GB, free: 10.92 MB / 0.6667 GB
Notification: Performance of sort global known variables: time 3.91e-07/0.6277, allocations: 0 / 0.8215 GB, free: 10.92 MB / 0.6667 GB
Notification: Performance of remove unused functions: time 0.001136/0.6288, allocations: 351.7 kB / 0.8218 GB, free: 10.58 MB / 0.6667 GB
Notification: Model statistics after passing the back-end for simulation:
 * Number of independent subsystems: 10
 * Number of states: 3 (firstOrder2.y,firstOrder1.y,firstOrder4.y)
 * Number of discrete variables: 18 ($whenCondition2,$whenCondition1,m_flow_pulse5.T_start,m_flow_pulse5.count,m_flow_pulse6.T_start,m_flow_pulse6.count,$whenCondition4,$whenCondition3,m_flow_pulse1.T_start,m_flow_pulse1.count,m_flow_pulse2.T_start,m_flow_pulse2.count,$whenCondition6,$whenCondition5,m_flow_pulse3.T_start,m_flow_pulse3.count,m_flow_pulse4.T_start,m_flow_pulse4.count)
 * Number of discrete states: 6 (m_flow_pulse4.count,m_flow_pulse3.count,m_flow_pulse2.count,m_flow_pulse1.count,m_flow_pulse6.count,m_flow_pulse5.count)
 * Number of clocked states: 0 ()
 * Top-level inputs: 0
Notification: Strong component statistics for simulation (47):
 * Single equations (assignments): 35
 * Array equations: 0
 * Algorithm blocks: 0
 * Record equations: 0
 * When equations: 12
 * If-equations: 0
 * Equation systems (not torn): 0
 * Torn equation systems: 0
 * Mixed (continuous/discrete) equation systems: 0
Notification: Performance of Backend phase and start with SimCode phase: time 0.0006511/0.6295, allocations: 463.5 kB / 0.8223 GB, free: 10.12 MB / 0.6667 GB
Notification: Performance of simCode: created initialization part: time 0.001923/0.6314, allocations: 1.179 MB / 0.8234 GB, free: 8.836 MB / 0.6667 GB
Notification: Performance of simCode: created event and clocks part: time 4.989e-06/0.6314, allocations: 1.188 kB / 0.8234 GB, free: 8.836 MB / 0.6667 GB
Notification: Performance of simCode: created simulation system equations: time 0.0006871/0.6321, allocations: 381 kB / 0.8238 GB, free: 8.465 MB / 0.6667 GB
Notification: Performance of simCode: created of all other equations (e.g. parameter, nominal, assert, etc): time 0.001227/0.6333, allocations: 396.7 kB / 0.8242 GB, free: 8.102 MB / 0.6667 GB
Notification: Performance of simCode: created linear, non-linear and system jacobian parts: time 0.003032/0.6363, allocations: 1.98 MB / 0.8261 GB, free: 6.059 MB / 0.6667 GB
Notification: Performance of simCode: some other stuff during SimCode phase: time 0.0004753/0.6368, allocations: 0.5652 MB / 0.8267 GB, free: 5.465 MB / 0.6667 GB
Notification: Performance of simCode: alias equations: time 0.001525/0.6383, allocations: 1.115 MB / 0.8277 GB, free: 4.352 MB / 0.6667 GB
Notification: Performance of simCode: all other stuff during SimCode phase: time 0.0003885/0.6387, allocations: 196.3 kB / 0.8279 GB, free: 4.16 MB / 0.6667 GB
Notification: Performance of SimCode: time 2.364e-06/0.6387, allocations: 0 / 0.8279 GB, free: 4.16 MB / 0.6667 GB
Notification: Performance of Templates: time 0.02792/0.6667, allocations: 19.6 MB / 0.8471 GB, free: 0.8867 MB / 0.6823 GB
"
[Timeout remaining time 659]
make -j1 -f ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.makefile [Timeout 660]
(rm -f ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.pipe ; mkfifo ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.pipe ; head -c 1048576 < ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.pipe >> ../files/ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.sim & ./ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance  -abortSlowSimulation -alarm=1200 -s gbode -gbnls=internal -gberr=embedded -gbm=radauIIA3 -emit_protected -lv LOG_STATS > ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.pipe 2>&1) [Timeout 1200]
diffSimulationResults("ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat","/mnt/ReferenceFiles/ThermofluidStream-main-regression/ReferenceData/ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_ref.mat","/var/lib/jenkins/ws/OpenModelicaLibraryTestingWork/OpenModelicaLibraryTesting/files/ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance.diff",relTol=0.003,relTolDiffMinMax=0.003,rangeDelta=0.001) [Timeout 660]
"Error: Could not read variable CPUtime in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable CPUtime from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable EventCounter in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable EventCounter from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.H0 in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.H0 from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Hf in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Hf from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.MM in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.MM from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.R_s in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.R_s from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Tlimit in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.Tlimit from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[3] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[3] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[4] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[4] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[5] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[5] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[6] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[6] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[7] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.ahigh[7] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[3] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[3] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[4] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[4] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[5] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[5] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[6] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[6] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[7] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.alow[7] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.bhigh[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.Air.DryAirNasa.data.blow[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.H0 in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.H0 from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Hf in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Hf from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.MM in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.MM from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.R_s in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.R_s from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Tlimit in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.Tlimit from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[3] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[3] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[4] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[4] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[5] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[5] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[6] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[6] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[7] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.ahigh[7] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[3] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[3] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[4] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[4] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[5] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[5] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[6] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[6] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[7] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.alow[7] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.bhigh[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable _GlobalScope.ThermofluidStream.Media.myMedia.IdealGases.Common.SingleGasesData.Air.blow[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable dropOfCommons.instanceNameColor[1] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable dropOfCommons.instanceNameColor[1] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable dropOfCommons.instanceNameColor[2] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable dropOfCommons.instanceNameColor[2] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable dropOfCommons.instanceNameColor[3] in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable dropOfCommons.instanceNameColor[3] from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateA1.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateA1.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateA2.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateA2.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateA3.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateA3.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateB1.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateB1.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateB2.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateB2.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateB4.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateB4.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable massFlowRateC4.m_flow_fixed in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable massFlowRateC4.m_flow_fixed from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable sinkA1.inlet.der(m_flow) in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable sinkA1.inlet.der(m_flow) from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable sinkA2.inlet.der(m_flow) in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable sinkA2.inlet.der(m_flow) from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable sinkA3.inlet.der(m_flow) in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable sinkA3.inlet.der(m_flow) from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
Error: Could not read variable sinkC4.inlet.der(m_flow) in file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat.
Warning: Get data of variable sinkC4.inlet.der(m_flow) from file ThermofluidStream_dev_ThermofluidStream.Idealized.Tests.Topology.SplitterNeglectInertance_res.mat failed!
"
[Timeout remaining time 660]
Reference file matches
[Calling sys.exit(0), Time elapsed: 4.5233498234301805]