Running: ./testmodel.py --libraries=/home/hudson/saved_omc/libraries/.openmodelica/libraries --ompython_omhome=/usr ModelicaTest_3.2.2_ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection.conf.json loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo", uses=false) loadFile("/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.2+maint.om/package.mo", uses=false) Using package ModelicaTest with version 3.2.2 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.2+maint.om/package.mo) Using package Modelica with version 3.2.3 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo) Using package Complex with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo) Using package ModelicaServices with version 4.0.0 (/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo) Running command: translateModel(ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection,tolerance=1e-06,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="ModelicaTest_3.2.2_ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection") translateModel(ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection,tolerance=1e-06,outputFormat="empty",numberOfIntervals=5000,variableFilter="",fileNamePrefix="ModelicaTest_3.2.2_ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection") Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaServices 4.0.0+maint.om/package.mo): time 0.001053/0.001053, allocations: 106.1 kB / 16.42 MB, free: 6.031 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Complex 4.0.0+maint.om/package.mo): time 0.001208/0.001208, allocations: 184.8 kB / 17.35 MB, free: 5.602 MB / 14.72 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/Modelica 3.2.3+maint.om/package.mo): time 1.292/1.292, allocations: 205.1 MB / 223.2 MB, free: 12.23 MB / 190.1 MB Notification: Performance of loadFile(/home/hudson/saved_omc/libraries/.openmodelica/libraries/ModelicaTest 3.2.2+maint.om/package.mo): time 0.169/0.169, allocations: 39.96 MB / 310.6 MB, free: 4.016 MB / 254.1 MB Notification: Performance of FrontEnd - Absyn->SCode: time 1.187e-05/1.187e-05, allocations: 2.281 kB / 436.4 MB, free: 11.77 MB / 318.1 MB Notification: Performance of NFInst.instantiate(ModelicaTest.Fluid.Dissipation.Verifications.HeatTransfer.General.kc_approxForcedConvection): time 0.00217/0.002189, allocations: 2.086 MB / 438.5 MB, free: 9.672 MB / 318.1 MB Notification: Performance of NFInst.instExpressions: time 0.001383/0.003585, allocations: 1.301 MB / 439.8 MB, free: 8.363 MB / 318.1 MB Notification: Performance of NFInst.updateImplicitVariability: time 4.909e-05/0.003645, allocations: 3.938 kB / 439.8 MB, free: 8.359 MB / 318.1 MB Notification: Performance of NFTyping.typeComponents: time 0.0001614/0.003812, allocations: 71.59 kB / 439.9 MB, free: 8.289 MB / 318.1 MB Notification: Performance of NFTyping.typeBindings: time 0.0001081/0.003928, allocations: 75.45 kB / 439.9 MB, free: 8.215 MB / 318.1 MB Notification: Performance of NFTyping.typeClassSections: time 0.0003386/0.004279, allocations: 187.3 kB / 440.1 MB, free: 8.031 MB / 318.1 MB Notification: Performance of NFFlatten.flatten: time 0.0002239/0.004512, allocations: 322.8 kB / 440.4 MB, free: 7.715 MB / 318.1 MB Notification: Performance of NFFlatten.resolveConnections: time 2.574e-05/0.004544, allocations: 13.12 kB / 440.5 MB, free: 7.703 MB / 318.1 MB Notification: Performance of NFEvalConstants.evaluate: time 0.0001127/0.004662, allocations: 151.5 kB / 440.6 MB, free: 7.555 MB / 318.1 MB Notification: Performance of NFSimplifyModel.simplify: time 0.0001345/0.004805, allocations: 151.5 kB / 440.8 MB, free: 7.406 MB / 318.1 MB Notification: Performance of NFPackage.collectConstants: time 1.503e-05/0.004826, allocations: 8 kB / 440.8 MB, free: 7.398 MB / 318.1 MB Notification: Performance of NFFlatten.collectFunctions: time 0.0002946/0.005125, allocations: 267.6 kB / 441 MB, free: 7.137 MB / 318.1 MB Notification: Performance of combineBinaries: time 0.0001959/0.00533, allocations: 384.4 kB / 441.4 MB, free: 6.758 MB / 318.1 MB Notification: Performance of replaceArrayConstructors: time 0.0001128/0.005449, allocations: 272.8 kB / 441.7 MB, free: 6.488 MB / 318.1 MB Notification: Performance of NFVerifyModel.verify: time 2.372e-05/0.005478, allocations: 19.94 kB / 441.7 MB, free: 6.469 MB / 318.1 MB Notification: Performance of FrontEnd: time 1.076e-05/0.005493, allocations: 7.938 kB / 441.7 MB, free: 6.461 MB / 318.1 MB Notification: Model statistics after passing the front-end and creating the data structures used by the back-end: * Number of equations: 133 (35) * Number of variables: 262 (36) Notification: Performance of Bindings: time 0.001024/0.006521, allocations: 1.754 MB / 443.4 MB, free: 4.594 MB / 318.1 MB Notification: Performance of FunctionAlias: time 0.0001706/0.006698, allocations: 205.5 kB / 443.6 MB, free: 4.402 MB / 318.1 MB Notification: Performance of Early Inline: time 0.0005321/0.007238, allocations: 0.8656 MB / 444.5 MB, free: 3.508 MB / 318.1 MB Notification: Performance of simplify1: time 2.212e-05/0.007268, allocations: 27.95 kB / 444.5 MB, free: 3.48 MB / 318.1 MB Notification: Performance of Alias: time 0.0001401/0.007413, allocations: 200.7 kB / 444.7 MB, free: 3.246 MB / 318.1 MB Notification: Performance of simplify2: time 1.442e-05/0.007432, allocations: 19.98 kB / 444.8 MB, free: 3.227 MB / 318.1 MB Notification: Performance of Events: time 9.63e-05/0.007533, allocations: 107.8 kB / 444.9 MB, free: 3.121 MB / 318.1 MB Notification: Performance of Detect States: time 0.0001315/0.007673, allocations: 199.6 kB / 445.1 MB, free: 2.914 MB / 318.1 MB Notification: Performance of Partitioning: time 0.000229/0.007908, allocations: 293.6 kB / 445.3 MB, free: 2.605 MB / 318.1 MB Error: Internal error NBSlice.fillDependencyArray failed because number of flattened indices 1 for dependency input_mflow_0.y could not be divided by the body size 3 without rest. Error: Internal error NBAdjacency.Matrix.createPseudo failed for: [ARRY] (3) m_flow = {(input_mflow_0.y * eta[1]) / eta[3], (input_mflow_0.y * eta[2]) / eta[3], input_mflow_0.y} ($RES_BND_64) Error: Internal error NBAdjacency.Matrix.create failed to create adjacency matrix for system: System Variables (50/306) *************************** (1) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.lambda = {lambda[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (2) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.eta = {eta[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (min = {0.0 for $i1 in 1:3}) (3) [DISC] (9) final enumeration Modelica.Fluid.Dissipation.Utilities.Types.kc_general(Rough, Middle, Finest)[3, 3] m_flow_IN_con_3.target = {Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Finest for $i1 in 1:3} (4) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.eta_wall = {eta[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (min = {0.0 for $i1 in 1:3}) (5) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.cp = {cp[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (6) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.m_flow = {m_flow[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (7) [ALGB] (9) Real[3, 3] m_flow_IN_con_3.perimeter = {perimeter for $m_flow_IN_con_31 in 1:3} (8) [ALGB] (3) Real[3] $FUN_19 (9) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.rho = {rho[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (min = {0.0 for $i1 in 1:3}) (10) [ALGB] (9) Real[3, 3] m_flow_IN_con_2.perimeter = {perimeter for $m_flow_IN_con_21 in 1:3} (11) [ALGB] (3) Real[3] $FUN_18 (12) [ALGB] (9) Real[3, 3] m_flow_IN_con_1.perimeter = {perimeter for $m_flow_IN_con_11 in 1:3} (13) [ALGB] (3) Real[3] $FUN_17 (14) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.lambda = {lambda[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (15) [ALGB] (3) Real[3] $FUN_16 (16) [ALGB] (3) Real[3] $FUN_15 (17) [ALGB] (3) Real[3] $FUN_14 (18) [ALGB] (3) Real[3] $FUN_13 (19) [ALGB] (3) Real[3] $FUN_12 (20) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.m_flow = {m_flow[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (21) [ALGB] (3) Real[3] $FUN_11 (22) [ALGB] (3) Real[3] $FUN_10 (23) [ALGB] (9) Real[3, 3] m_flow_IN_con_1.A_cross = {A_cross for $m_flow_IN_con_11 in 1:3} (24) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.eta = {eta[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (min = {0.0 for $i1 in 1:3}) (25) [ALGB] (3) protected Real[3] m_flow = {(input_mflow_0.y * eta[1]) / eta[3], (input_mflow_0.y * eta[2]) / eta[3], input_mflow_0.y} (26) [DISC] (9) final enumeration Modelica.Fluid.Dissipation.Utilities.Types.kc_general(Rough, Middle, Finest)[3, 3] m_flow_IN_con_2.target = {Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Middle for $i1 in 1:3} (27) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.eta_wall = {eta[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (min = {0.0 for $i1 in 1:3}) (28) [ALGB] (9) Real[3, 3] m_flow_IN_con_3.A_cross = {A_cross for $m_flow_IN_con_31 in 1:3} (29) [ALGB] (3) Real[3] Nu_3 (30) [ALGB] (3) Real[3] Nu_2 (31) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.rho = {rho[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (min = {0.0 for $i1 in 1:3}) (32) [ALGB] (3) Real[3] Nu_1 (33) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.lambda = {lambda[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (34) [ALGB] (3) Real[3] Re_1 (35) [DISC] (1) Boolean $TEV_4 (36) [DISC] (1) Boolean $TEV_3 (37) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.m_flow = {m_flow[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (38) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.eta = {eta[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (min = {0.0 for $i1 in 1:3}) (39) [DISC] (9) final enumeration Modelica.Fluid.Dissipation.Utilities.Types.kc_general(Rough, Middle, Finest)[3, 3] m_flow_IN_con_1.target = {Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Rough for $i1 in 1:3} (40) [ALGB] (9) Real[3, 3] m_flow_IN_var_1.cp = {cp[$m_flow_IN_var_11] for $m_flow_IN_var_11 in 1:3} (41) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.eta_wall = {eta[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (min = {0.0 for $i1 in 1:3}) (42) [ALGB] (9) Real[3, 3] m_flow_IN_var_3.rho = {rho[$m_flow_IN_var_31] for $m_flow_IN_var_31 in 1:3} (min = {0.0 for $i1 in 1:3}) (43) [ALGB] (1) Real input_mflow_0.y (44) [ALGB] (3) Real[3] $FUN_9 (45) [ALGB] (9) Real[3, 3] m_flow_IN_con_2.A_cross = {A_cross for $m_flow_IN_con_21 in 1:3} (46) [ALGB] (3) Real[3] $FUN_8 (47) [ALGB] (3) Real[3] $FUN_7 (48) [ALGB] (9) Real[3, 3] m_flow_IN_var_2.cp = {cp[$m_flow_IN_var_21] for $m_flow_IN_var_21 in 1:3} (49) [ALGB] (3) Real[3] $FUN_6 (50) [ALGB] (3) Real[3] $FUN_5 System Equations (38/144) *************************** (1) [FOR-] (3) ($RES_BND_20) (1) [----] for $i1 in 1:3 loop (1) [----] [SCAL] (1) m_flow_IN_var_1[$i1].lambda = lambda[$i1] ($RES_BND_21) (1) [----] end for; (2) [FOR-] (3) ($RES_BND_22) (2) [----] for $i1 in 1:3 loop (2) [----] [SCAL] (1) m_flow_IN_var_1[$i1].rho = rho[$i1] ($RES_BND_23) (2) [----] end for; (3) [FOR-] (3) ($RES_BND_24) (3) [----] for $i1 in 1:3 loop (3) [----] [SCAL] (1) m_flow_IN_var_1[$i1].eta_wall = eta[$i1] ($RES_BND_25) (3) [----] end for; (4) [FOR-] (3) ($RES_$AUX_75) (4) [----] for $i1 in 1:3 loop (4) [----] [SCAL] (1) Re_1[$i1] = $FUN_7[$i1] ($RES_$AUX_76) (4) [----] end for; (5) [FOR-] (3) ($RES_BND_40) (5) [----] for $i1 in 1:3 loop (5) [----] [SCAL] (1) m_flow_IN_var_2[$i1].rho = rho[$i1] ($RES_BND_41) (5) [----] end for; (6) [FOR-] (3) ($RES_BND_26) (6) [----] for $i1 in 1:3 loop (6) [----] [SCAL] (1) m_flow_IN_var_1[$i1].m_flow = m_flow[$i1] ($RES_BND_27) (6) [----] end for; (7) [FOR-] (3) ($RES_$AUX_77) (7) [----] for $i1 in 1:3 loop (7) [----] [SCAL] (1) Nu_1[$i1] = $FUN_8[$i1] ($RES_$AUX_78) (7) [----] end for; (8) [FOR-] (3) ($RES_BND_42) (8) [----] for $i1 in 1:3 loop (8) [----] [SCAL] (1) m_flow_IN_var_2[$i1].eta_wall = eta[$i1] ($RES_BND_43) (8) [----] end for; (9) [FOR-] (3) ($RES_BND_28) (9) [----] for $i1 in 1:3 loop (9) [----] [SCAL] (1) m_flow_IN_con_2[$i1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Middle ($RES_BND_29) (9) [----] end for; (10) [FOR-] (3) ($RES_$AUX_79) (10) [----] for $i1 in 1:3 loop (10) [----] [SCAL] (1) Nu_2[$i1] = $FUN_13[$i1] ($RES_$AUX_80) (10) [----] end for; (11) [FOR-] (3) ($RES_BND_44) (11) [----] for $i1 in 1:3 loop (11) [----] [SCAL] (1) m_flow_IN_var_2[$i1].m_flow = m_flow[$i1] ($RES_BND_45) (11) [----] end for; (12) [FOR-] (3) ($RES_BND_60) (12) [----] for $i1 in 1:3 loop (12) [----] [SCAL] (1) m_flow_IN_var_3[$i1].eta_wall = eta[$i1] ($RES_BND_61) (12) [----] end for; (13) [FOR-] (3) ($RES_BND_46) (13) [----] for $i1 in 1:3 loop (13) [----] [SCAL] (1) m_flow_IN_con_3[$i1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Finest ($RES_BND_47) (13) [----] end for; (14) [FOR-] (3) ($RES_BND_62) (14) [----] for $i1 in 1:3 loop (14) [----] [SCAL] (1) m_flow_IN_var_3[$i1].m_flow = m_flow[$i1] ($RES_BND_63) (14) [----] end for; (15) [FOR-] (3) ($RES_BND_48) (15) [----] for $i1 in 1:3 loop (15) [----] [SCAL] (1) m_flow_IN_con_3[$i1].A_cross = A_cross ($RES_BND_49) (15) [----] end for; (16) [ARRY] (3) m_flow = {(input_mflow_0.y * eta[1]) / eta[3], (input_mflow_0.y * eta[2]) / eta[3], input_mflow_0.y} ($RES_BND_64) (17) [FOR-] (3) ($RES_BND_10) (17) [----] for $i1 in 1:3 loop (17) [----] [SCAL] (1) m_flow_IN_con_1[$i1].target = Modelica.Fluid.Dissipation.Utilities.Types.kc_general.Rough ($RES_BND_11) (17) [----] end for; (18) [FOR-] (3) ($RES_BND_12) (18) [----] for $i1 in 1:3 loop (18) [----] [SCAL] (1) m_flow_IN_con_1[$i1].A_cross = A_cross ($RES_BND_13) (18) [----] end for; (19) [FOR-] (3) ($RES_BND_14) (19) [----] for $i1 in 1:3 loop (19) [----] [SCAL] (1) m_flow_IN_con_1[$i1].perimeter = perimeter ($RES_BND_15) (19) [----] end for; (20) [FOR-] (15) ($RES_$AUX_65) (20) [----] for $i1 in 1:3 loop (20) [----] [TUPL] (5) ($FUN_15[$i1], $FUN_16[$i1], $FUN_17[$i1], $FUN_18[$i1], $FUN_19[$i1]) = Modelica.Fluid.Dissipation.HeatTransfer.General.kc_approxForcedConvection(m_flow_IN_con_3[$i1], m_flow_IN_var_3[$i1]) ($RES_$AUX_66) (20) [----] end for; (21) [SCAL] (1) $TEV_3 = time < input_mflow_0.startTime ($RES_EVT_86) (22) [FOR-] (3) ($RES_BND_30) (22) [----] for $i1 in 1:3 loop (22) [----] [SCAL] (1) m_flow_IN_con_2[$i1].A_cross = A_cross ($RES_BND_31) (22) [----] end for; (23) [FOR-] (3) ($RES_$AUX_81) (23) [----] for $i1 in 1:3 loop (23) [----] [SCAL] (1) Nu_3[$i1] = $FUN_18[$i1] ($RES_$AUX_82) (23) [----] end for; (24) [SCAL] (1) $TEV_4 = time < (input_mflow_0.startTime + input_mflow_0.duration) ($RES_EVT_87) (25) [FOR-] (3) ($RES_BND_16) (25) [----] for $i1 in 1:3 loop (25) [----] [SCAL] (1) m_flow_IN_var_1[$i1].cp = cp[$i1] ($RES_BND_17) (25) [----] end for; (26) [FOR-] (15) ($RES_$AUX_67) (26) [----] for $i1 in 1:3 loop (26) [----] [TUPL] (5) ($FUN_10[$i1], $FUN_11[$i1], $FUN_12[$i1], $FUN_13[$i1], $FUN_14[$i1]) = Modelica.Fluid.Dissipation.HeatTransfer.General.kc_approxForcedConvection(m_flow_IN_con_2[$i1], m_flow_IN_var_2[$i1]) ($RES_$AUX_68) (26) [----] end for; (27) [FOR-] (3) ($RES_BND_32) (27) [----] for $i1 in 1:3 loop (27) [----] [SCAL] (1) m_flow_IN_con_2[$i1].perimeter = perimeter ($RES_BND_33) (27) [----] end for; (28) [FOR-] (3) ($RES_BND_18) (28) [----] for $i1 in 1:3 loop (28) [----] [SCAL] (1) m_flow_IN_var_1[$i1].eta = eta[$i1] ($RES_BND_19) (28) [----] end for; (29) [FOR-] (15) ($RES_$AUX_69) (29) [----] for $i1 in 1:3 loop (29) [----] [TUPL] (5) ($FUN_5[$i1], $FUN_6[$i1], $FUN_7[$i1], $FUN_8[$i1], $FUN_9[$i1]) = Modelica.Fluid.Dissipation.HeatTransfer.General.kc_approxForcedConvection(m_flow_IN_con_1[$i1], m_flow_IN_var_1[$i1]) ($RES_$AUX_70) (29) [----] end for; (30) [FOR-] (3) ($RES_BND_34) (30) [----] for $i1 in 1:3 loop (30) [----] [SCAL] (1) m_flow_IN_var_2[$i1].cp = cp[$i1] ($RES_BND_35) (30) [----] end for; (31) [FOR-] (3) ($RES_BND_50) (31) [----] for $i1 in 1:3 loop (31) [----] [SCAL] (1) m_flow_IN_con_3[$i1].perimeter = perimeter ($RES_BND_51) (31) [----] end for; (32) [FOR-] (3) ($RES_BND_36) (32) [----] for $i1 in 1:3 loop (32) [----] [SCAL] (1) m_flow_IN_var_2[$i1].eta = eta[$i1] ($RES_BND_37) (32) [----] end for; (33) [FOR-] (3) ($RES_BND_52) (33) [----] for $i1 in 1:3 loop (33) [----] [SCAL] (1) m_flow_IN_var_3[$i1].cp = cp[$i1] ($RES_BND_53) (33) [----] end for; (34) [FOR-] (3) ($RES_BND_38) (34) [----] for $i1 in 1:3 loop (34) [----] [SCAL] (1) m_flow_IN_var_2[$i1].lambda = lambda[$i1] ($RES_BND_39) (34) [----] end for; (35) [FOR-] (3) ($RES_BND_54) (35) [----] for $i1 in 1:3 loop (35) [----] [SCAL] (1) m_flow_IN_var_3[$i1].eta = eta[$i1] ($RES_BND_55) (35) [----] end for; (36) [SCAL] (1) input_mflow_0.y = input_mflow_0.offset + (if $TEV_3 then 0.0 else if $TEV_4 then (input_mflow_0.height * (time - input_mflow_0.startTime)) / input_mflow_0.duration else input_mflow_0.height) ($RES_SIM_9) (37) [FOR-] (3) ($RES_BND_56) (37) [----] for $i1 in 1:3 loop (37) [----] [SCAL] (1) m_flow_IN_var_3[$i1].lambda = lambda[$i1] ($RES_BND_57) (37) [----] end for; (38) [FOR-] (3) ($RES_BND_58) (38) [----] for $i1 in 1:3 loop (38) [----] [SCAL] (1) m_flow_IN_var_3[$i1].rho = rho[$i1] ($RES_BND_59) (38) [----] end for;