!WRF:DRIVER_LAYER:INTEGRATION ! MODULE module_integrate CONTAINS RECURSIVE SUBROUTINE integrate ( grid ) USE module_domain USE module_driver_constants USE module_nesting USE module_configure USE module_timing USE module_utility IMPLICIT NONE ! Input data. TYPE(domain) , POINTER :: grid ! module_integrate:integrate ! ! This is a driver-level routine that controls the integration of a ! domain and subdomains rooted at the domain. ! ! The integrate routine takes a domain pointed to by the argument ! grid and advances the domain and its associated nests from the ! grid's current time, stored within grid%domain_clock, to a given time ! forward in the simulation, stored as grid%stop_subtime. The ! stop_subtime value is arbitrary and does not have to be the same as ! time that the domain finished integrating. The simulation stop time ! for the grid is known to the grid's clock (grid%domain_clock) and that ! is checked with a call to domain_clockisstoptime prior to beginning the ! loop over time period that is specified by the ! current time/stop_subtime interval. ! ! The clock, the simulation stop time for the domain, and other timing ! aspects for the grid are set up in the routine ! (setup_timekeeping) at the time ! that the domain is initialized. ! The lower-level time library and the type declarations for the times ! and time intervals used are defined either in ! external/esmf_time_f90/module_utility.F90 or in ! external/io_esmf/module_utility.F90 depending on a build-time decision to ! incorporate either the embedded ESMF subset implementation contained in ! external/esmf_time_f90 or to use a site-specific installation of the ESMF ! library. This decision is made during the configuration step of the WRF ! build process. Note that arithmetic and comparison is performed on these ! data types using F90 operator overloading, also defined in that library. ! ! This routine is the lowest level of the WRF Driver Layer and for the most ! part the WRF routines that are called from here are in the topmost level ! of the Mediation Layer. Mediation layer routines typically are not ! defined in modules. Therefore, the routines that this routine calls ! have explicit interfaces specified in an interface block in this routine. ! ! As part of the Driver Layer, this routine is intended to be non model-specific ! and so a minimum of WRF-specific logic is coded at this level. Rather, there ! are a number of calls to mediation layer routines that contain this logic, some ! of which are merely stubs in WRF Mediation Layer that sits below this routine ! in the call tree. The routines that integrate calls in WRF are defined in ! share/mediation_integrate.F. ! ! Flow of control ! ! 1. Check to see that the domain is not finished ! by testing the value returned by domain_clockisstoptime for the ! domain. ! ! 2. Model_to_grid_config_rec is called to load the local config_flags ! structure with the configuration information for the grid stored ! in model_config_rec and indexed by the grid's unique integer id. These ! structures are defined in frame/module_configure.F. ! ! 3. The current time of the domain is retrieved from the domain's clock ! using domain_get_current_time. ! ! 4. Iterate forward while the current time is less than the stop subtime. ! ! 4.a. Start timing for this iteration (only on node zero in distributed-memory runs) ! ! 4.b. Call med_setup_step to allow the mediation layer to ! do anything that's needed to call the solver for this domain. In WRF this means setting ! the indices into the 4D tracer arrays for the domain. ! ! 4.c. Check for any nests that need to be started up at this time. This is done ! calling the logical function nests_to_open (defined in ! frame/module_nesting.F) which returns true and the index into the current domain's list ! of children to use for the nest when one needs to be started. ! ! 4.c.1 Call alloc_and_configure_domain to allocate ! the new nest and link it as a child of this grid. ! ! 4.c.2 Call setup_Timekeeping for the nest. ! ! 4.c.3 Initialize the nest's arrays by calling med_nest_initial. This will ! either interpolate data from this grid onto the nest, read it in from a file, or both. In a restart run, this ! is also where the nest reads in its restart file. ! ! 4.d If a nest was opened above, check for and resolve overlaps (this is not implemented in WRF 2.0, which ! supports multiple nests on the same level but does not support overlapping). ! ! 4.e Give the mediation layer an opportunity to do something before the solver is called by ! calling med_before_solve_io. In WRF this is the point at which history and ! restart data is output. ! ! 4.f Call solve_interface which calls the solver that advance the domain ! one time step, then advance the domain's clock by calling domain_clockadvance. ! The enclosing WHILE loop around this section is for handling other domains ! with which this domain may overlap. It is not active in WRF 2.0 and only ! executes one trip. ! ! 4.g Call med_calc_model_time and med_after_solve_io, which are stubs in WRF. ! ! 4.h Iterate over the children of this domain (DO kid = 1, max_nests) and check each child pointer to see ! if it is associated (and therefore, active). ! ! 4.h.1 Force the nested domain boundaries from this domain by calling med_nest_force. ! ! 4.h.2 Setup the time period over which the nest is to run. Sine the current grid has been advanced one time step ! and the nest has not, the start for the nest is this grid's current time minus one time step. The nest's stop_subtime ! is the current time, bringing the nest up the same time level as this grid, its parent. ! ! 4.h.3 Recursively call this routine, integrate, to advance the nest's time. Since it is recursive, this will ! also advance all the domains who are nests of this nest and so on. In other words, when this call returns, all ! the domains rooted at the nest will be at the current time. ! ! 4.h.4 Feedback data from the nested domain back onto this domain by calling med_nest_feedback. ! ! 4.i Write the time to compute this grid and its subtree. This marks the end of the loop begun at step 4, above. ! ! 5. Give the mediation layer an opportunity to do I/O at the end of the sequence of steps that brought the ! grid up to stop_subtime with a call to med_last_solve_io. In WRF, this ! is used to generate the final history and/or restart output when the domain reaches the end of it's integration. ! There is logic here to make sure this occurs correctly on a nest, since the nest may finish before its parent. ! ! Local data. CHARACTER*32 :: outname, rstname TYPE(domain) , POINTER :: grid_ptr , new_nest TYPE(domain) :: intermediate_grid INTEGER :: step INTEGER :: nestid , kid LOGICAL :: a_nest_was_opened INTEGER :: fid , rid LOGICAL :: lbc_opened REAL :: time, btime, bfrq CHARACTER*256 :: message, message2 TYPE (grid_config_rec_type) :: config_flags LOGICAL , EXTERNAL :: wrf_dm_on_monitor INTEGER :: idum1 , idum2 , ierr , open_status LOGICAL :: should_do_last_io ! interface INTERFACE ! mediation-supplied solver SUBROUTINE solve_interface ( grid ) USE module_domain TYPE (domain) grid END SUBROUTINE solve_interface ! mediation-supplied routine to allow driver to pass time information ! down to mediation/model layer SUBROUTINE med_calc_model_time ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_calc_model_time ! mediation-supplied routine that gives mediation layer opportunity to ! perform I/O before the call to the solve routine SUBROUTINE med_before_solve_io ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_before_solve_io ! mediation-supplied routine that gives mediation layer opportunity to ! perform I/O after the call to the solve routine SUBROUTINE med_after_solve_io ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_after_solve_io ! mediation-supplied routine that gives mediation layer opportunity to ! perform I/O to initialize a new nest SUBROUTINE med_pre_nest_initial ( parent , newid , config_flags ) USE module_domain USE module_configure TYPE (domain), POINTER :: parent INTEGER, INTENT(IN) :: newid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_pre_nest_initial SUBROUTINE med_nest_initial ( parent , grid , config_flags ) USE module_domain USE module_configure TYPE (domain), POINTER :: grid , parent TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_nest_initial ! mediation-supplied routine that gives mediation layer opportunity to ! provide parent->nest forcing SUBROUTINE med_nest_force ( parent , grid , config_flags ) USE module_domain USE module_configure TYPE (domain), POINTER :: grid, parent TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_nest_force #ifdef MOVE_NESTS SUBROUTINE med_nest_move ( parent , grid ) USE module_domain USE module_configure TYPE (domain), POINTER :: grid , parent END SUBROUTINE med_nest_move #endif ! mediation-supplied routine that gives mediation layer opportunity to ! provide parent->nest feedback SUBROUTINE med_nest_feedback ( parent , grid , config_flags ) USE module_domain USE module_configure TYPE (domain), POINTER :: grid , parent TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_nest_feedback ! mediation-supplied routine that gives mediation layer opportunity to ! perform I/O prior to the close of this call to integrate SUBROUTINE med_last_solve_io ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_last_solve_io ! mediation-supplied routine that gives mediation layer opportunity to ! perform setup before iteration over steps in this call to integrate SUBROUTINE med_setup_step ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_setup_step ! mediation-supplied routine that gives mediation layer opportunity to ! perform setup before iteration over steps in this call to integrate SUBROUTINE med_endup_step ( grid , config_flags ) USE module_domain USE module_configure TYPE (domain) grid TYPE (grid_config_rec_type) config_flags END SUBROUTINE med_endup_step ! mediation-supplied routine that intializes the nest from the grid ! by interpolation SUBROUTINE Setup_Timekeeping( grid ) USE module_domain TYPE(domain), POINTER :: grid END SUBROUTINE SUBROUTINE dfi_accumulate( grid ) USE module_domain TYPE(domain), POINTER :: grid END SUBROUTINE END INTERFACE ! This allows us to reference the current grid from anywhere beneath ! this point for debugging purposes. CALL set_current_grid_ptr( grid ) IF ( .NOT. domain_clockisstoptime( grid ) ) THEN CALL model_to_grid_config_rec ( grid%id , model_config_rec , config_flags ) IF ( config_flags%grid_allowed ) THEN CALL domain_clockprint ( 150, grid, 'DEBUG: top of integrate(),' ) DO WHILE ( .NOT. domain_clockisstopsubtime(grid) ) IF ( wrf_dm_on_monitor() ) THEN CALL start_timing END IF CALL med_setup_step ( grid , config_flags ) a_nest_was_opened = .false. ! for each nest whose time has come... DO WHILE ( nests_to_open( grid , nestid , kid ) ) ! nestid is index into model_config_rec (module_configure) of the grid ! to be opened; kid is index into an open slot in grid's list of children a_nest_was_opened = .true. CALL med_pre_nest_initial ( grid , nestid , config_flags ) CALL alloc_and_configure_domain ( domain_id = nestid , & grid = new_nest , & parent = grid , & kid = kid ) CALL Setup_Timekeeping (new_nest) CALL med_nest_initial ( grid , new_nest , config_flags ) IF ( grid%dfi_stage == DFI_STARTFWD ) THEN CALL wrf_dfi_startfwd_init(new_nest) ENDIF END DO IF ( a_nest_was_opened ) THEN CALL set_overlaps ( grid ) ! find overlapping and set pointers END IF ! Accumulation calculation for DFI CALL dfi_accumulate ( grid ) CALL med_before_solve_io ( grid , config_flags ) grid_ptr => grid DO WHILE ( ASSOCIATED( grid_ptr ) ) CALL set_current_grid_ptr( grid_ptr ) CALL wrf_debug( 100 , 'module_integrate: calling solve interface ' ) CALL solve_interface ( grid_ptr ) CALL domain_clockadvance ( grid_ptr ) CALL wrf_debug( 100 , 'module_integrate: back from solve interface ' ) ! print lots of time-related information for testing ! switch this on with namelist variable self_test_domain CALL domain_time_test( grid_ptr, 'domain_clockadvance' ) grid_ptr => grid_ptr%sibling END DO CALL set_current_grid_ptr( grid ) CALL med_calc_model_time ( grid , config_flags ) CALL med_after_solve_io ( grid , config_flags ) grid_ptr => grid DO WHILE ( ASSOCIATED( grid_ptr ) ) DO kid = 1, max_nests IF ( ASSOCIATED( grid_ptr%nests(kid)%ptr ) ) THEN CALL set_current_grid_ptr( grid_ptr%nests(kid)%ptr ) ! Recursive -- advance nests from previous time level to this time level. CALL wrf_debug( 100 , 'module_integrate: calling med_nest_force ' ) CALL med_nest_force ( grid_ptr , grid_ptr%nests(kid)%ptr , config_flags ) CALL wrf_debug( 100 , 'module_integrate: back from med_nest_force ' ) grid_ptr%nests(kid)%ptr%start_subtime = & domain_get_current_time(grid) - domain_get_time_step(grid) grid_ptr%nests(kid)%ptr%stop_subtime = & domain_get_current_time(grid) CALL integrate ( grid_ptr%nests(kid)%ptr ) CALL wrf_debug( 100 , 'module_integrate: back from recursive call to integrate ' ) CALL wrf_debug( 100 , 'module_integrate: calling med_nest_feedback ' ) CALL med_nest_feedback ( grid_ptr , grid_ptr%nests(kid)%ptr , config_flags ) CALL wrf_debug( 100 , 'module_integrate: back from med_nest_feedback ' ) #ifdef MOVE_NESTS IF ( .NOT. domain_clockisstoptime( head_grid ) ) THEN CALL med_nest_move ( grid_ptr , grid_ptr%nests(kid)%ptr ) ENDIF #endif END IF END DO grid_ptr => grid_ptr%sibling END DO CALL set_current_grid_ptr( grid ) ! Report on the timing for a single time step. IF ( wrf_dm_on_monitor() ) THEN CALL domain_clock_get ( grid, current_timestr=message2 ) #if (EM_CORE == 1) if (config_flags%use_adaptive_time_step) then WRITE ( message , FMT = '("main (dt=",F6.2,"): time ",A," on domain ",I3)' ) grid%dt, TRIM(message2), grid%id else WRITE ( message , FMT = '("main: time ",A," on domain ",I3)' ) TRIM(message2), grid%id endif #else WRITE ( message , FMT = '("main: time ",A," on domain ",I3)' ) TRIM(message2), grid%id #endif CALL end_timing ( TRIM(message) ) END IF CALL med_endup_step ( grid , config_flags ) END DO ! Accumulation calculation for DFI CALL dfi_accumulate ( grid ) ! Avoid double writes on nests if this is not really the last time; ! Do check for write if the parent domain is ending. IF ( grid%id .EQ. 1 ) THEN ! head_grid CALL med_last_solve_io ( grid , config_flags ) ELSE ! zip up the tree and see if any ancestor is at its stop time should_do_last_io = domain_clockisstoptime( head_grid ) grid_ptr => grid DO WHILE ( grid_ptr%id .NE. 1 ) IF ( domain_clockisstoptime( grid_ptr ) ) should_do_last_io = .TRUE. grid_ptr => grid_ptr%parents(1)%ptr ENDDO IF ( should_do_last_io ) THEN CALL med_last_solve_io ( grid , config_flags ) ENDIF ENDIF ENDIF END IF END SUBROUTINE integrate END MODULE module_integrate