Initializing CUDA...
CUDA initialized with 1 GPU
AMReX (19.11-338-g35faf597a624) initialized
Calling Setup()
Calling ReadParameters()
 WARNING: burning_cutoff_density not supplied in the inputs file
 WARNING: setting burning_cutoff_density = base_cutoff_density
reading extern runtime parameters ...
 ERROR: problem in the namelist
Calling VariableSetup()
 Calling set_method_params()
 
 Initializing Helmholtz EOS and using Coulomb corrections.
 
Calling BCSetup()
 Calling init_base_state_geometry()
Calling Init()
Calling InitData()
                                                            
------------------------------------------------------------------------------
 reading initial model
          640 points found in the initial model file
            6  variables found in the initial model file
------------------------------------------------------------------------------
 model file mapping, level:        0
 dr of MAESTRO base state =                                 562500.0000
 dr of input file data =                                    562500.0000
 
 maximum radius (cell-centered) of input model =            359718750.0
  
 setting r_cutoff to           365
 radius at r_cutoff     205593750.0000000     
 
 Maximum HSE Error =     0.6051370840E-04
    (after putting initial model into base state arrays, and
     for density < base_cutoff_density)
------------------------------------------------------------------------------
 

Writing plotfile reacting_bubble-3d_pltInitData after InitData
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 1.252195965
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Doing initial projection
Calling nodal solver
MLMG: Initial rhs               = 0
MLMG: Initial residual (resid0) = 0
MLMG: No iterations needed
MLMG: Timers: Solve = 0.062034542 Iter = 0 Bottom = 0
Done calling nodal solver

Writing plotfile reacting_bubble-3d_pltafter_InitProj after InitProj
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 1.073511927
Call to firstdt for level 0 gives dt_lev = 0.0004741795139
Multiplying dt_lev by init_shrink; dt_lev = 0.0004741795139
Minimum firstdt over all levels = 0.0004741795139
Doing initial divu iteration #1
Calling nodal solver
MLMG: Initial rhs               = 2054.812696
MLMG: Initial residual (resid0) = 2054.812696
MLMG: Final Iter. 7 resid, resid/bnorm = 5.590798935e-10, 2.720831415e-13
MLMG: Timers: Solve = 3.595898809 Iter = 3.537625903 Bottom = 0.033125613
Done calling nodal solver
Call to estdt for level 0 gives dt_lev = 0.1719927642
Minimum estdt over all levels = 0.1719927642
Call to estdt at end of istep_divu_iter = 1 gives dt = 0.1719927642
Multiplying dt by init_shrink; dt = 0.1719927642
Ignoring this new dt since it's larger than the previous dt = 0.0004741795139

Writing plotfile reacting_bubble-3d_pltafter_DivuIter after final DivuIter
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 1.105925017
Doing initial pressure iteration #1

Timestep 0 starts with TIME = 0 DT = 0.0004741795139

Cell Count:
Level 0, 1327104 cells
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
<<< STEP 1 : react state >>>
<<< STEP 2 : make w0 >>>
<<< STEP 3 : create MAC velocities >>>
MLMG: Initial rhs               = 2728630.345
MLMG: Initial residual (resid0) = 2728630.345
MLMG: Final Iter. 9 resid, resid/bnorm = 1.658638939e-05, 6.0786502e-12
MLMG: Timers: Solve = 0.341007466 Iter = 0.314895858 Bottom = 0.259971525
<<< STEP 4 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 4a: thermal conduct >>>
<<< STEP 5 : react state >>>
<<< STEP 6 : make new S and new w0 >>>
<<< STEP 7 : create MAC velocities >>>
MLMG: Initial rhs               = 2728626.155
MLMG: Initial residual (resid0) = 8729.505839
MLMG: Final Iter. 5 resid, resid/bnorm = 0.0002248510136, 8.240447789e-11
MLMG: Timers: Solve = 0.202410722 Iter = 0.183747383 Bottom = 0.153748752
<<< STEP 8 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 8a: thermal conduct >>>
<<< STEP 9 : react state >>>
<<< STEP 10: make new S >>>
<<< STEP 11: update and project new velocity >>>
Calling nodal solver
MLMG: Initial rhs               = 1.157552621e+10
MLMG: Initial residual (resid0) = 1.157552621e+10
MLMG: Final Iter. 8 resid, resid/bnorm = 0.005317687988, 4.593906048e-13
MLMG: Timers: Solve = 0.23763953 Iter = 0.235290855 Bottom = 0.179428014
Done calling nodal solver

Timestep 0 ends with TIME = 0.0004741795139 DT = 0.0004741795139
Timing summary:
Advection  :4.530466246 seconds
MAC Proj   :0.751454614 seconds
Nodal Proj :0.287397355 seconds
Reactions  :0.254524892 seconds
Misc       :0.082460962 seconds
Base State :0.017752666 seconds
Time to advance time step: 5.90643598

Writing plotfile 0 after all initialization
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 0.889034208
Calling Evolve()

Timestep 1 starts with TIME = 0 DT = 0.0004741795139

Cell Count:
Level 0, 1327104 cells
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
<<< STEP 1 : react state >>>
<<< STEP 2 : make w0 >>>
<<< STEP 3 : create MAC velocities >>>
MLMG: Initial rhs               = 1308193.213
MLMG: Initial residual (resid0) = 1308193.213
MLMG: Final Iter. 8 resid, resid/bnorm = 0.0001233436633, 9.428550929e-11
MLMG: Timers: Solve = 0.323440484 Iter = 0.321377917 Bottom = 0.273483938
<<< STEP 4 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 4a: thermal conduct >>>
<<< STEP 5 : react state >>>
<<< STEP 6 : make new S and new w0 >>>
<<< STEP 7 : create MAC velocities >>>
MLMG: Initial rhs               = 1308193.247
MLMG: Initial residual (resid0) = 0.9819746694
MLMG: Final Iter. 4 resid, resid/bnorm = 3.557779928e-05, 2.719613434e-11
MLMG: Timers: Solve = 0.16516521 Iter = 0.163182846 Bottom = 0.139164254
<<< STEP 8 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 8a: thermal conduct >>>
<<< STEP 9 : react state >>>
<<< STEP 10: make new S >>>
<<< STEP 11: update and project new velocity >>>
Calling nodal solver
MLMG: Initial rhs               = 5488884.015
MLMG: Initial residual (resid0) = 5488884.015
MLMG: Final Iter. 8 resid, resid/bnorm = 2.406537533e-06, 4.384384014e-13
MLMG: Timers: Solve = 0.243808283 Iter = 0.240929873 Bottom = 0.185033156
Done calling nodal solver

Timestep 1 ends with TIME = 0.0004741795139 DT = 0.0004741795139
Timing summary:
Advection  :2.645835867 seconds
MAC Proj   :0.628272916 seconds
Nodal Proj :0.284803204 seconds
Reactions  :0.218025028 seconds
Misc       :0.084745247 seconds
Base State :0.002507054 seconds
Time to advance time step: 3.86185266

Writing plotfile 1
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 0.869730536
Call to estdt for level 0 gives dt_lev = 0.2012294724
Minimum estdt over all levels = 0.2012294724

Timestep 2 starts with TIME = 0.0004741795139 DT = 0.0005215974653

Cell Count:
Level 0, 1327104 cells
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
<<< STEP 1 : react state >>>
<<< STEP 2 : make w0 >>>
<<< STEP 3 : create MAC velocities >>>
MLMG: Initial rhs               = 1417785.252
MLMG: Initial residual (resid0) = 1417785.252
MLMG: Final Iter. 8 resid, resid/bnorm = 0.0001352318213, 9.538244324e-11
MLMG: Timers: Solve = 0.285898797 Iter = 0.28387472 Bottom = 0.232012003
<<< STEP 4 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 4a: thermal conduct >>>
<<< STEP 5 : react state >>>
<<< STEP 6 : make new S and new w0 >>>
<<< STEP 7 : create MAC velocities >>>
MLMG: Initial rhs               = 1417789.529
MLMG: Initial residual (resid0) = 60994.35243
MLMG: Final Iter. 6 resid, resid/bnorm = 3.04913533e-05, 2.150626216e-11
MLMG: Timers: Solve = 0.238739855 Iter = 0.23671553 Bottom = 0.200803059
<<< STEP 8 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 8a: thermal conduct >>>
<<< STEP 9 : react state >>>
<<< STEP 10: make new S >>>
<<< STEP 11: update and project new velocity >>>
Calling nodal solver
MLMG: Initial rhs               = 6063790.017
MLMG: Initial residual (resid0) = 6063790.017
MLMG: Final Iter. 8 resid, resid/bnorm = 2.598855644e-06, 4.285860224e-13
MLMG: Timers: Solve = 0.247458344 Iter = 0.24483569 Bottom = 0.189065687
Done calling nodal solver

Timestep 2 ends with TIME = 0.0009957769792 DT = 0.0005215974653
Timing summary:
Advection  :2.536987057 seconds
MAC Proj   :0.665056622 seconds
Nodal Proj :0.288826105 seconds
Reactions  :0.211489828 seconds
Misc       :0.075176456 seconds
Base State :0.002621264 seconds
Time to advance time step: 3.777694545

Writing plotfile 2
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 0.866018191
Call to estdt for level 0 gives dt_lev = 0.2012849721
Minimum estdt over all levels = 0.2012849721

Timestep 3 starts with TIME = 0.0009957769792 DT = 0.0005737572118

Cell Count:
Level 0, 1327104 cells
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
<<< STEP 1 : react state >>>
<<< STEP 2 : make w0 >>>
<<< STEP 3 : create MAC velocities >>>
MLMG: Initial rhs               = 1588645.934
MLMG: Initial residual (resid0) = 1588645.934
MLMG: Final Iter. 8 resid, resid/bnorm = 0.0001472164295, 9.266786661e-11
MLMG: Timers: Solve = 0.334046632 Iter = 0.332058062 Bottom = 0.284043678
<<< STEP 4 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 4a: thermal conduct >>>
<<< STEP 5 : react state >>>
<<< STEP 6 : make new S and new w0 >>>
<<< STEP 7 : create MAC velocities >>>
MLMG: Initial rhs               = 1588650.64
MLMG: Initial residual (resid0) = 22571.20547
MLMG: Final Iter. 6 resid, resid/bnorm = 3.303529684e-05, 2.079456365e-11
MLMG: Timers: Solve = 0.207738376 Iter = 0.205725544 Bottom = 0.169825061
<<< STEP 8 : advect base >>>
            :  density_advance >>>
            :   tracer_advance >>>
            : enthalpy_advance >>>
<<< STEP 8a: thermal conduct >>>
<<< STEP 9 : react state >>>
<<< STEP 10: make new S >>>
<<< STEP 11: update and project new velocity >>>
Calling nodal solver
MLMG: Initial rhs               = 6670311.018
MLMG: Initial residual (resid0) = 6670311.018
MLMG: Final Iter. 8 resid, resid/bnorm = 3.050081432e-06, 4.572622511e-13
MLMG: Timers: Solve = 0.240952784 Iter = 0.23817095 Bottom = 0.18232309
Done calling nodal solver

Timestep 3 ends with TIME = 0.001569534191 DT = 0.0005737572118
Timing summary:
Advection  :2.538818378 seconds
MAC Proj   :0.688885682 seconds
Nodal Proj :0.282226269 seconds
Reactions  :0.21203461 seconds
Misc       :0.075726409 seconds
Base State :0.002757825 seconds
Time to advance time step: 3.797845244

Writing plotfile 3
inner sponge: r_sp      , r_tp      :   0.186468750000E+09    0.224718750000E+09
 
Time to write plotfile: 0.939845451

Total Time: 62.52910816
Unused ParmParse Variables:
  [TOP]::maestro.v(nvals = 1)  :: [1]
  [TOP]::amr.ref_ratio(nvals = 6)  :: [2, 2, 2, 2, 2, 2]
  [TOP]::system.regtest_reduction(nvals = 1)  :: [1]
  [TOP]::amr.check_file(nvals = 1)  :: [reacting_bubble-3d_chk]
  [TOP]::amr.checkpoint_files_output(nvals = 1)  :: [0]

Total GPU global memory (MB): 12066
Free  GPU global memory (MB): 7905
[The         Arena] space (MB): 9049
[The  Device Arena] space (MB): 8
[The Managed Arena] space (MB): 8
[The  Pinned Arena] space (MB): 8
AMReX (19.11-338-g35faf597a624) finalized