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data_output_particle_mod.f90 @ 4838

Last change on this file since 4838 was 4828, checked in by Giersch, 4 years ago
Copyright updated to year 2021, interface pmc_sort removed to accelarate the nesting code
Property svn:keywords set to `Id`
File size: 88.8 KB

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[4778]	1	!> @file data_output_particle_mod.f90
	2	!--------------------------------------------------------------------------------------------------!
	3	! This file is part of the PALM model system.
	4	!
	5	! PALM is free software: you can redistribute it and/or modify it under the terms of the GNU General
	6	! Public License as published by the Free Software Foundation, either version 3 of the License, or
	7	! (at your option) any later version.
	8	!
	9	! PALM is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the
	10	! implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General
	11	! Public License for more details.
	12	!
	13	! You should have received a copy of the GNU General Public License along with PALM. If not, see
	14	! <http://www.gnu.org/licenses/>.
	15	!
[4828]	16	! Copyright 1997-2021 Leibniz Universitaet Hannover
[4778]	17	!--------------------------------------------------------------------------------------------------!
	18	!
	19	! Current revisions:
	20	! -----------------
	21	!
	22	!
	23	! Former revisions:
	24	! -----------------
	25	! $Id: data_output_particle_mod.f90 4828 2021-01-05 11:21:41Z raasch $
[4792]	26	! file re-formatted to follow the PALM coding standard
	27	!
	28	! 4779 2020-11-09 17:45:22Z suehring
[4779]	29	! Avoid overlong lines and unused variables
	30	!
	31	! 4778 2020-11-09 13:40:05Z raasch
[4778]	32	! Initial implementation (K. Ketelsen)
	33	!
	34	!
[4792]	35	!--------------------------------------------------------------------------------------------------!
[4778]	36	! Description:
	37	! ------------
	38	!> Output of particle time series
	39	!--------------------------------------------------------------------------------------------------!
	40	MODULE data_output_particle_mod
	41
	42	#if defined( __parallel )
[4792]	43	USE MPI
[4778]	44	#endif
	45
	46	#if defined( __netcdf4 )
[4792]	47	USE NETCDF
[4778]	48	#endif
	49
[4792]	50	USE, INTRINSIC :: ISO_C_BINDING
[4778]	51
[4792]	52	USE kinds, &
	53	ONLY: dp, idp, isp, iwp, sp, wp
[4778]	54
[4792]	55	USE indices, &
	56	ONLY: nbgp, nnx, nny, nx, nxl, nxlg, nxr, nxrg, ny, nyn, nyng, nys, nysg, nz, nzb, nzt
[4778]	57
[4792]	58	USE control_parameters, &
	59	ONLY: dt_dopts, end_time, simulated_time
[4778]	60
[4792]	61	USE pegrid, &
	62	ONLY: comm1dx, comm1dy, comm2d, myid, myidx, myidy, npex, npey, numprocs, pdims
[4778]	63
[4792]	64	USE particle_attributes, &
	65	ONLY: data_output_pts, grid_particles, grid_particle_def, number_of_output_particles, &
	66	particles, particle_type, prt_count, pts_id_file, pts_increment, pts_percentage, &
	67	oversize, unlimited_dimension
[4778]	68
[4792]	69	USE shared_memory_io_mod, &
	70	ONLY: sm_class
[4778]	71
[4792]	72	USE data_output_netcdf4_module, &
	73	ONLY: netcdf4_finalize, netcdf4_get_error_message, netcdf4_init_dimension, &
	74	netcdf4_init_module, netcdf4_init_variable, netcdf4_open_file, &
	75	netcdf4_stop_file_header_definition, netcdf4_write_attribute, netcdf4_write_variable
[4778]	76
[4792]	77	USE cpulog, &
	78	ONLY: cpu_log, log_point_s
[4778]	79
[4792]	80	IMPLICIT NONE
[4778]	81
[4792]	82	PRIVATE
	83	SAVE
[4778]	84
	85
[4792]	86	LOGICAL, PUBLIC :: dop_active = .FALSE.
[4778]	87
[4792]	88	!
	89	!-- Variables for restart
	90	INTEGER(iwp), PUBLIC :: dop_prt_axis_dimension
	91	INTEGER(iwp), PUBLIC :: dop_last_active_particle
[4778]	92
[4792]	93	!
	94	!-- kk Private module variables can be declared inside the submodule
	95	INTEGER, PARAMETER :: max_nr_variables = 128
	96	INTEGER, PARAMETER :: nr_fixed_variables = 16
[4778]	97
[4792]	98	CHARACTER(LEN=32) :: file_name !< Name of NetCDF file
[4778]	99
[4792]	100	INTEGER(iwp) :: end_local_numbering
	101	INTEGER(iwp) :: io_end_index
	102	INTEGER(iwp) :: io_start_index !< Start index of the output area on IO thread
	103	INTEGER(iwp) :: nr_particles_pe !< Number of particles assigned for output on this thread
	104	INTEGER(iwp) :: nr_particles_rest !< Numbere of rest Particle (ireg. distribution)
	105	INTEGER(iwp) :: nr_particles_out !< Total number od particles assigned for output
	106	INTEGER(iwp) :: nr_time_values !< Number of values on time axis
	107	INTEGER(iwp) :: pe_end_index
	108	INTEGER(iwp) :: pe_start_index !< Start index of the output area on this thread
	109	INTEGER(iwp) :: start_local_numbering !< Start increment 1 numbering on this thread
[4778]	110
[4792]	111	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: io_indices !< Indices on IO processes
	112	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: mo_indices !< Indices for model communicator
	113	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: remote_nr_particles
	114	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: rma_particles !< Start address and number of remote particles
	115	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: sh_indices !< Indices in shared memory group
[4778]	116
[4792]	117	LOGICAL :: irregular_distribubtion !< irregular distribution of output particlesexit
[4778]	118
[4792]	119	REAL(sp), ALLOCATABLE, DIMENSION(:) :: time_axis_values !< time axis Values
[4778]	120
[4792]	121	TYPE var_def
	122	INTEGER(iwp) :: var_id
	123	CHARACTER(LEN=32) :: name
	124	CHARACTER(LEN=32) :: units
	125	LOGICAL :: is_integer = .FALSE.
	126	END TYPE var_def
[4778]	127
[4792]	128	TYPE(sm_class) :: part_io !< manage communicator for particle IO
[4778]	129
[4792]	130	TYPE(var_def), DIMENSION(nr_fixed_variables) :: fix_variables
	131	TYPE(var_def), DIMENSION(max_nr_variables) :: variables
[4778]	132
	133	!
[4792]	134	!-- NetCDF
	135	INTEGER(iwp) :: file_id = -1 !< id of Netcdf file
	136	INTEGER(iwp) :: nr_fix_variables !< Number of fixed variables scheduled for output
	137	INTEGER(iwp) :: nr_variables !< Number of variables scheduled for output
[4778]	138
[4792]	139	TYPE dimension_id
	140	INTEGER(iwp) :: prt
	141	INTEGER(iwp) :: time
	142	END TYPE dimension_id
[4778]	143
[4792]	144	TYPE variable_id
	145	INTEGER(iwp) :: prt
	146	INTEGER(iwp) :: time
	147	END TYPE variable_id
[4778]	148
[4792]	149	TYPE(dimension_id) :: did
	150	TYPE(variable_id) :: var_id
[4778]	151
[4792]	152	!
	153	!-- Shared memory buffer
	154	INTEGER(iwp) :: win_prt_i = -1 !< integer MPI shared Memory window
	155	INTEGER(iwp) :: win_prt_r = -1 !< real MPI shared Memory window
	156	INTEGER(iwp), POINTER, CONTIGUOUS, DIMENSION(:) :: out_buf_i !< integer output buffer
	157	REAL(sp), POINTER, CONTIGUOUS, DIMENSION(:) :: out_buf_r !< real output buffer
[4778]	158
	159	!
[4792]	160	!-- Particle list in file
	161	INTEGER(idp), ALLOCATABLE, DIMENSION(:) :: part_id_list_file
[4778]	162
[4792]	163	LOGICAL :: part_list_in_file
	164
[4778]	165	!
[4792]	166	!-- RMA window
[4778]	167	#if defined( __parallel )
[4792]	168	INTEGER(iwp) :: win_rma_buf_i
	169	INTEGER(iwp) :: win_rma_buf_r
[4778]	170	#endif
	171
[4792]	172	INTEGER(iwp) :: initial_number_of_active_particles
	173	INTEGER(iwp), ALLOCATABLE, DIMENSION(:) :: remote_indices !< particle nubmer of the remodte partices,
	174	!< used as indices in the output array
	175	INTEGER(iwp), POINTER, DIMENSION(:) :: transfer_buffer_i !< rma window to provide data, which can be
	176	!< fetch via MPI_Get
	177	REAL(sp), POINTER, DIMENSION(:) :: transfer_buffer_r !< Same for REAL
[4778]	178
[4792]	179	!
	180	!-- Public subroutine Interface
	181	INTERFACE dop_init
	182	MODULE PROCEDURE dop_init
	183	END INTERFACE dop_init
[4778]	184
[4792]	185	INTERFACE dop_output_tseries
	186	MODULE PROCEDURE dop_output_tseries
	187	END INTERFACE dop_output_tseries
[4778]	188
[4792]	189	INTERFACE dop_finalize
	190	MODULE PROCEDURE dop_finalize
	191	END INTERFACE dop_finalize
[4778]	192
	193	#if defined( __parallel )
[4792]	194	INTERFACE dop_alloc_rma_mem
	195	MODULE PROCEDURE dop_alloc_rma_mem_i1
	196	MODULE PROCEDURE dop_alloc_rma_mem_r1
	197	END INTERFACE dop_alloc_rma_mem
[4778]	198	#endif
	199
[4792]	200	PUBLIC dop_init, dop_output_tseries, dop_finalize
[4778]	201	#if defined( __parallel )
[4792]	202	PUBLIC dop_alloc_rma_mem ! Must be PUBLIC on NEC, although it is only used in submodule
[4778]	203	#endif
	204
	205
	206	CONTAINS
	207
	208
[4792]	209	!--------------------------------------------------------------------------------------------------!
	210	! Description:
	211	! ------------
	212	!
	213	!--------------------------------------------------------------------------------------------------!
	214	SUBROUTINE dop_init( read_restart )
	215	IMPLICIT NONE
	216
	217	INTEGER(iwp) :: i !<
[4778]	218	#if defined( __parallel )
[4792]	219	INTEGER(iwp) :: ierr !< MPI error code
[4778]	220	#endif
[4792]	221	INTEGER(iwp) :: nr_local_last_pe !< Number of output particles on myid == numprocs-2
	222	INTEGER(idp) :: nr_particles_8 !< Total number of particles in 64 bit
	223	INTEGER(iwp) :: nr_particles_local !< total number of particles scheduled for output on this thread
[4778]	224
[4792]	225	INTEGER(idp), DIMENSION(0:numprocs-1) :: nr_particles_all_8
	226	INTEGER(iwp), DIMENSION(0:numprocs-1) :: nr_particles_all_s
	227	INTEGER(iwp), DIMENSION(0:numprocs-1) :: nr_particles_all_r
[4778]	228
[4792]	229	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: io_indices_s
	230	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: mo_indices_s
	231	INTEGER(iwp), ALLOCATABLE, DIMENSION(:,:) :: sh_indices_s
[4778]	232
[4792]	233	LOGICAL, INTENT(IN) :: read_restart
[4778]	234
[4792]	235	REAL(dp) :: xnr_part !< Must be 64 Bit REAL
[4778]	236
	237
[4792]	238	part_list_in_file = (pts_id_file /= ' ')
[4778]	239
[4792]	240	IF ( .NOT. part_list_in_file ) THEN
	241	IF ( .NOT. read_restart) THEN
[4778]	242
[4792]	243	CALL set_indef_particle_nr
	244
	245	CALL count_output_particles( nr_particles_local )
	246
	247	nr_particles_all_s = 0
	248	nr_particles_all_s(myid) = nr_particles_local
	249
[4778]	250	#if defined( __parallel )
[4792]	251	CALL MPI_ALLREDUCE( nr_particles_all_s, nr_particles_all_r, SIZE( nr_particles_all_s ), &
	252	MPI_INTEGER, MPI_SUM, comm2d, ierr )
[4778]	253	#else
[4792]	254	nr_particles_all_r = nr_particles_all_s
[4778]	255	#endif
	256
[4792]	257	initial_number_of_active_particles = SUM( nr_particles_all_r )
[4778]	258
[4792]	259	start_local_numbering = 1
	260	end_local_numbering = nr_particles_all_r(0)
[4778]	261
[4792]	262	IF ( myid > 0 ) THEN
	263	DO i = 1, numprocs-1
	264	start_local_numbering = start_local_numbering+nr_particles_all_r(i-1)
	265	end_local_numbering = start_local_numbering+nr_particles_all_r(i)-1
	266	IF ( myid == i ) EXIT
	267	ENDDO
	268	ENDIF
[4778]	269
[4792]	270	nr_particles_all_8 = nr_particles_all_r ! Use 64 INTEGER, maybe more than 2 GB particles
	271	nr_particles_8 = SUM( nr_particles_all_8 )
	272	IF ( nr_particles_8 > 2000000000_idp ) THEN ! This module works only with 32 Bit INTEGER
	273	WRITE( 9, * ) 'Number of particles too large ', nr_particles_8 ; FLUSH( 9 )
[4778]	274	#if defined( __parallel )
[4792]	275	CALL MPI_ABORT( MPI_COMM_WORLD, 1, ierr )
[4778]	276	#endif
[4792]	277	ENDIF
	278	nr_particles_out = nr_particles_8 ! Total number of particles scheduled for output
[4778]	279
	280	!
[4792]	281	!-- Reserve space for additional particle
	282	IF ( number_of_output_particles > 0 ) THEN
	283	nr_particles_out = MAX( number_of_output_particles, nr_particles_out )
	284	ELSEIF ( oversize > 100.0_wp ) THEN
	285	xnr_part = nr_particles_out * oversize / 100.0_wp
	286	nr_particles_out = xnr_part
	287	ENDIF
	288	ELSE
	289	nr_particles_out = dop_prt_axis_dimension ! Get Number from restart file
	290	initial_number_of_active_particles = dop_last_active_particle
	291	ENDIF
[4778]	292
[4792]	293	ELSE
	294	CALL set_indef_particle_nr
	295	CALL dop_read_output_particle_list( nr_particles_out )
	296	ENDIF
	297	dop_prt_axis_dimension = nr_particles_out
	298
[4778]	299	!
[4792]	300	!-- The number of particles must be at least the number of MPI processes
	301	nr_particles_out = MAX( nr_particles_out, numprocs )
[4778]	302
	303
[4792]	304	nr_particles_pe = ( nr_particles_out + numprocs - 1 ) / numprocs ! Number of paricles scheduled for ouput on this thread
[4778]	305
[4792]	306	pe_start_index = myid * nr_particles_pe + 1 !Output numberimng on this thread
	307	pe_end_index = MIN( ( myid + 1 ) * nr_particles_pe, nr_particles_out )
[4778]	308
[4792]	309	irregular_distribubtion = .FALSE.
[4778]	310	#if defined( __parallel )
	311	!
[4792]	312	!-- In case of few particles, it can happen that not only the last thread gets fewer output
	313	!-- particles. In this case, the local number of particles on thread numprocs-1 will be < 1.
	314	!-- If this happens, irregular distribution of output particles will be used.
	315	IF ( myid == numprocs-1 ) THEN
	316	nr_local_last_pe = pe_end_index-pe_start_index + 1
	317	ELSE
	318	nr_local_last_pe = 0
	319	ENDIF
	320	CALL MPI_BCAST( nr_local_last_pe, 1, MPI_INTEGER, numprocs-1, comm2d, ierr )
[4778]	321	#else
[4792]	322	nr_local_last_pe = nr_particles_pe
[4778]	323	#endif
[4792]	324	IF ( nr_local_last_pe < 1 ) THEN
	325	irregular_distribubtion = .TRUE.
	326	CALL dop_setup_ireg_distribution
	327	ENDIF
[4778]	328
	329
[4792]	330	IF ( .NOT. read_restart .AND. .NOT. part_list_in_file ) THEN
	331	CALL set_particle_number
	332	ENDIF
[4778]	333
[4792]	334	IF ( part_list_in_file ) THEN
	335	CALL dop_find_particle_in_outlist
	336	ENDIF
[4778]	337
[4792]	338	CALL part_io%sm_init_data_output_particles( )
[4778]	339
[4792]	340	ALLOCATE( sh_indices_s(2,0:part_io%sh_npes-1) )
	341	ALLOCATE( sh_indices(2,0:part_io%sh_npes-1) )
[4778]	342
	343
	344	#if defined( __parallel )
[4792]	345	sh_indices_s = 0
	346	sh_indices_s(1,part_io%sh_rank) = pe_start_index
	347	sh_indices_s(2,part_io%sh_rank) = pe_end_index
[4778]	348
[4792]	349	CALL MPI_ALLREDUCE( sh_indices_s, sh_indices, 2*part_io%sh_npes, MPI_INTEGER, MPI_SUM, &
	350	part_io%comm_shared, ierr )
[4778]	351
[4792]	352	io_start_index = sh_indices(1,0) ! output numbering on actual IO thread
	353	io_end_index = sh_indices(2,part_io%sh_npes-1)
[4778]	354	#else
[4792]	355	io_start_index = pe_start_index ! output numbering
	356	io_end_index = pe_end_index
[4778]	357	#endif
	358
	359
	360	#if defined( __parallel )
[4792]	361	CALL MPI_BCAST( part_io%io_npes, 1, MPI_INTEGER, 0, part_io%comm_shared, ierr )
[4778]	362	#endif
[4792]	363	ALLOCATE( io_indices(2,0:part_io%io_npes-1) )
	364	IF ( part_io%iam_io_pe ) THEN
	365	ALLOCATE( io_indices_s(2,0:part_io%io_npes-1) )
[4778]	366
[4792]	367	io_indices_s = 0
	368	io_indices_s(1,part_io%io_rank) = io_start_index
	369	io_indices_s(2,part_io%io_rank) = io_end_index
[4778]	370
	371	#if defined( __parallel )
[4792]	372	CALL MPI_ALLREDUCE( io_indices_s, io_indices, 2 * part_io%io_npes, MPI_INTEGER, MPI_SUM, &
	373	part_io%comm_io, ierr )
[4778]	374	#else
[4792]	375	io_indices = io_indices_s
[4778]	376	#endif
	377
[4792]	378	ENDIF
[4778]	379
	380	#if defined( __parallel )
[4792]	381	CALL MPI_BCAST( io_indices, SIZE( io_indices ), MPI_INTEGER, 0, part_io%comm_shared, ierr )
[4778]	382	#endif
	383
[4792]	384	ALLOCATE( remote_nr_particles(2,0:numprocs-1) )
	385	ALLOCATE( rma_particles(2,0:numprocs-1) )
[4778]	386
[4792]	387	ALLOCATE( mo_indices(2,0:numprocs-1) )
	388	ALLOCATE( mo_indices_s(2,0:numprocs-1) )
[4778]	389
[4792]	390	mo_indices_s = 0
	391	mo_indices_s(1,myid) = pe_start_index
	392	mo_indices_s(2,myid) = pe_end_index
[4778]	393
	394	#if defined( __parallel )
[4792]	395	CALL MPI_ALLREDUCE( mo_indices_s, mo_indices, 2 * numprocs, MPI_INTEGER, MPI_SUM, comm2d, ierr )
[4778]	396	#else
[4792]	397	mo_indices = mo_indices_s
[4778]	398	#endif
	399
[4792]	400	!-- Allocate output buffer
[4778]	401	#if defined( __parallel )
[4792]	402	CALL part_io%sm_allocate_shared( out_buf_r, io_start_index, io_end_index, win_prt_r )
	403	CALL part_io%sm_allocate_shared( out_buf_i, io_start_index, io_end_index, win_prt_i )
[4778]	404	#else
[4792]	405	ALLOCATE( out_buf_r(io_start_index:io_end_index) )
	406	ALLOCATE( out_buf_i(io_start_index:io_end_index) )
[4778]	407	#endif
	408
[4792]	409	!
	410	!-- NetCDF
	411	CALL dop_netcdf_setup( )
[4778]	412
	413	#if defined( __parallel )
[4792]	414	CALL MPI_BCAST( nr_fix_variables, 1, MPI_INTEGER, 0, part_io%comm_shared, ierr )
	415	CALL MPI_BCAST( nr_variables, 1, MPI_INTEGER, 0, part_io%comm_shared, ierr )
[4778]	416	#endif
	417
[4792]	418	CALL dop_count_remote_particles
[4778]	419
[4792]	420	CALL dop_write_fixed_variables
[4778]	421
[4792]	422	CALL deallocate_and_free
[4778]	423
[4792]	424	CALL dop_output_tseries
[4778]	425
[4792]	426	RETURN
[4778]	427
[4792]	428	CONTAINS
[4778]	429
	430
[4792]	431	!--------------------------------------------------------------------------------------------------!
	432	! Description:
	433	! ------------
	434	!
	435	!--------------------------------------------------------------------------------------------------!
	436	SUBROUTINE dop_setup_ireg_distribution
[4778]	437
[4792]	438	IMPLICIT NONE
[4778]	439
[4792]	440	nr_particles_pe = ( nr_particles_out ) / numprocs ! Number of paricles scheduled for ouput on this thread
[4778]	441
[4792]	442	nr_particles_rest = nr_particles_out - numprocs * nr_particles_pe
[4778]	443
[4792]	444	nr_particles_pe = nr_particles_pe + 1
	445	IF ( myid < nr_particles_rest ) THEN
	446	pe_start_index = myid * nr_particles_pe + 1 ! Output numberimng on this thread
	447	pe_end_index = MIN( ( myid + 1 ) * nr_particles_pe, nr_particles_out)
	448	ELSE
	449	pe_start_index = nr_particles_rest * ( nr_particles_pe ) &
	450	+ ( myid - nr_particles_rest ) * ( nr_particles_pe - 1 ) + 1 !Output numberimng on this thread
	451	pe_end_index = MIN( pe_start_index + nr_particles_pe - 2, nr_particles_out )
	452	ENDIF
[4778]	453
	454
[4792]	455	END SUBROUTINE dop_setup_ireg_distribution
	456
	457	END SUBROUTINE dop_init
	458
	459
	460	!--------------------------------------------------------------------------------------------------!
	461	! Description:
	462	! ------------
	463	!> Particle output on selected time steps
	464	!--------------------------------------------------------------------------------------------------!
	465	SUBROUTINE dop_output_tseries
	466
	467	IMPLICIT NONE
	468
	469	INTEGER(iwp) :: i !<
	470	INTEGER(iwp) :: return_value !< Return value data_output_netcdf4 .. routines
[4778]	471	#if defined( __parallel )
[4792]	472	INTEGER(iwp) :: ierr !< MPI error code
[4778]	473	#endif
[4792]	474	INTEGER(iwp), SAVE :: icount=0 !< count output steps
[4778]	475
[4792]	476	INTEGER(iwp), DIMENSION(2) :: bounds_origin, bounds_start, value_counts
[4778]	477
[4792]	478	REAl(wp), POINTER, CONTIGUOUS, DIMENSION(:) :: my_time
[4778]	479
[4792]	480	icount = icount + 1
[4778]	481
[4792]	482	CALL dop_delete_particle_number
[4778]	483
[4792]	484	IF ( part_list_in_file ) THEN
[4778]	485
[4792]	486	CALL dop_find_particle_in_outlist
	487	ELSE
	488	CALL dop_newly_generated_particles
	489	ENDIF
[4778]	490
[4792]	491	CALL dop_count_remote_particles
[4778]	492
[4792]	493	bounds_origin = 1
[4778]	494
[4792]	495	bounds_start(1) = io_start_index
	496	bounds_start(2) = icount
[4778]	497
[4792]	498	value_counts(1) = io_end_index-io_start_index + 1
	499	value_counts(2) = 1
	500
	501	DO i = 1, nr_variables
[4778]	502	#if defined( __netcdf4 )
[4792]	503	IF ( variables(i)%is_integer ) THEN
	504	out_buf_i = NF90_FILL_INT
	505	ELSE
	506	out_buf_r = NF90_FILL_REAL
	507	ENDIF
[4778]	508	#endif
	509
[4792]	510	CALL cpu_log( log_point_s(99), 'dop_fill_out_buf', 'start' )
	511	CALL dop_fill_out_buf (variables(i))
	512	CALL cpu_log( log_point_s(99), 'dop_fill_out_buf', 'stop' )
[4778]	513
[4792]	514	CALL cpu_log( log_point_s(88), 'dop_get_remote_particle', 'start' )
[4778]	515	#if defined( __parallel )
[4792]	516	CALL dop_get_remote_particle( variables(i)%is_integer )
[4778]	517	#endif
[4792]	518	CALL cpu_log( log_point_s(88), 'dop_get_remote_particle', 'stop' )
[4778]	519
[4792]	520	CALL cpu_log( log_point_s(89), 'particle NetCDF output', 'start' )
	521	CALL part_io%sm_node_barrier( )
	522	IF ( part_io%iam_io_pe ) THEN
	523	IF ( variables(i)%is_integer) THEN
	524	CALL netcdf4_write_variable( 'parallel', file_id, variables(i)%var_id, bounds_start, &
	525	value_counts, bounds_origin, .FALSE., &
	526	values_int32_1d=out_buf_i, return_value=return_value )
	527	ELSE
	528	CALL netcdf4_write_variable( 'parallel', file_id, variables(i)%var_id, bounds_start, &
	529	value_counts, bounds_origin, .FALSE., &
	530	values_real32_1d=out_buf_r, return_value=return_value)
	531	ENDIF
	532	ENDIF
	533	CALL part_io%sm_node_barrier( )
	534	CALL cpu_log( log_point_s(89), 'particle NetCDF output', 'stop' )
[4778]	535
	536	#if defined( __parallel )
[4792]	537	CALL MPI_BARRIER( comm2d, ierr ) !kk This Barrier is necessary, not sure why
[4778]	538	#endif
[4792]	539	ENDDO
[4778]	540
[4792]	541	CALL deallocate_and_free
[4778]	542
[4792]	543	!
	544	!-- Write Time value
	545	IF ( myid == 0 ) THEN
	546	ALLOCATE( my_time(1) )
	547	bounds_start(1) = icount
	548	value_counts(1) = 1
	549	my_time(1) = simulated_time
	550	IF ( unlimited_dimension ) THEN ! For workaround described in dop finalize
	551	time_axis_values(icount) = my_time(1)
	552	ELSE
	553	CALL netcdf4_write_variable( 'parallel', file_id, var_id%time, bounds_start(1:1), &
	554	value_counts(1:1), bounds_origin(1:1), .TRUE., &
	555	values_realwp_1d=my_time, return_value=return_value )
	556	ENDIF
	557	DEALLOCATE( my_time )
	558	ENDIF
[4778]	559
[4792]	560	RETURN
	561	END SUBROUTINE dop_output_tseries
[4778]	562
[4792]	563	!--------------------------------------------------------------------------------------------------!
	564	! Description:
	565	! ------------
	566	!
	567	!--------------------------------------------------------------------------------------------------!
	568	SUBROUTINE dop_finalize
	569
	570	IMPLICIT NONE
	571
[4779]	572	#if defined( __netcdf4 )
[4792]	573	INTEGER(iwp) :: ierr !< MPI error code
[4779]	574	#endif
[4792]	575	INTEGER(iwp) :: return_value !< Return value data_output_netcdf4 .. routines
[4779]	576	#if defined( __netcdf4 )
[4792]	577	INTEGER(iwp) :: var_len
[4779]	578	#endif
[4778]	579
[4792]	580	IF ( win_prt_i /= -1 ) THEN
	581	CALL part_io%sm_free_shared( win_prt_i )
	582	ENDIF
	583	IF ( win_prt_r /= -1 ) THEN
	584	CALL part_io%sm_free_shared( win_prt_r )
	585	ENDIF
[4778]	586
[4792]	587	IF ( file_id /= -1 .AND. part_io%iam_io_pe ) THEN
	588	CALL netcdf4_finalize( 'parallel', file_id, return_value )
	589	file_id = -1
[4778]	590
	591	#if defined( __netcdf4 )
	592	!
[4792]	593	!-- For yet unknown reasons it is not possible to write in parallel mode the time values to
	594	!-- NetCDF variable time.
	595	!-- This workaround closes the parallel file and writes the time values in sequential mode on
	596	!-- PE0.
	597	!-- kk This is a real quick and dirty workaround and the problem should be solved in the final
	598	!-- version !!!
	599	IF ( myid == 0 .AND. unlimited_dimension ) THEN
	600	ierr = NF90_OPEN( TRIM( file_name ), NF90_WRITE, file_id )
	601	ierr = NF90_INQUIRE_DIMENSION( file_id, did%time, LEN = var_len)
[4778]	602
[4792]	603	ierr = NF90_PUT_VAR( file_id, var_id%time, time_axis_values(1:var_len) )
[4778]	604
[4792]	605	ierr = NF90_CLOSE( file_id )
	606	ENDIF
[4778]	607	#endif
[4792]	608	ENDIF
[4778]	609
[4792]	610	RETURN
	611	END SUBROUTINE dop_finalize
[4778]	612
[4792]	613	!
	614	!--Private subroutines
[4778]	615
[4792]	616	!--------------------------------------------------------------------------------------------------!
	617	! Description:
	618	! ------------
[4778]	619	!
[4792]	620	!--------------------------------------------------------------------------------------------------!
	621	!
	622	!-- kk Not sure if necessary, but set ALL particle number to -1
	623	SUBROUTINE set_indef_particle_nr
[4778]	624
[4792]	625	IMPLICIT NONE
[4778]	626
[4792]	627	INTEGER(iwp) :: i !<
	628	INTEGER(iwp) :: j !<
	629	INTEGER(iwp) :: k !<
	630	INTEGER(iwp) :: n !<
[4778]	631
[4792]	632	DO i = nxl, nxr
	633	DO j = nys, nyn
	634	DO k = nzb+1, nzt
	635	DO n = 1, SIZE( grid_particles(k,j,i)%particles )
	636	grid_particles(k,j,i)%particles(n)%particle_nr = -1
	637	ENDDO
	638	ENDDO
	639	ENDDO
	640	ENDDO
[4778]	641
[4792]	642	RETURN
	643	END SUBROUTINE set_indef_particle_nr
[4778]	644
[4792]	645	!--------------------------------------------------------------------------------------------------!
	646	! Description:
	647	! ------------
	648	!> Count particles scheduled for output.
	649	!> Here pts_increment and pts_percentage are used to select output particles.
	650	!--------------------------------------------------------------------------------------------------!
	651	SUBROUTINE count_output_particles (pcount)
[4778]	652
[4792]	653	IMPLICIT NONE
[4778]	654
[4792]	655	INTEGER(iwp) :: i !<
	656	INTEGER(iwp) :: j !<
	657	INTEGER(iwp) :: k !<
	658	INTEGER(iwp) :: n !<
	659	INTEGER(iwp) :: n_all !< count all particles for MOD function
	660	INTEGER(iwp), INTENT(OUT) :: pcount !<
[4778]	661
[4792]	662	REAL(dp) :: finc
	663	REAL(dp) :: fcount
[4778]	664
	665
[4792]	666	pcount = 0
	667	IF ( pts_increment == 1 ) THEN
	668	pcount = SUM( prt_count )
	669	ELSE
	670	n_all = 0
	671	DO i = nxl, nxr
	672	DO j = nys, nyn
	673	DO k = nzb+1, nzt
	674	DO n = 1, prt_count(k,j,i)
	675	IF ( MOD( n_all, pts_increment ) == 0 ) THEN
	676	pcount = pcount + 1
	677	ENDIF
	678	n_all = n_all + 1
	679	ENDDO
	680	ENDDO
	681	ENDDO
	682	ENDDO
	683	ENDIF
[4778]	684
[4792]	685	IF ( pts_percentage < 100.0_wp ) THEN
[4778]	686
[4792]	687	finc = pts_percentage / 100
[4778]	688
[4792]	689	pcount = 0
	690	fcount = 0.0_wp
[4778]	691
[4792]	692	DO i = nxl, nxr
	693	DO j = nys, nyn
	694	DO k = nzb+1, nzt
	695	DO n = 1, prt_count(k,j,i)
	696	fcount = fcount + finc
	697	IF ( pcount < INT( fcount ) ) THEN
	698	pcount = pcount + 1
	699	ENDIF
	700	ENDDO
	701	ENDDO
	702	ENDDO
	703	ENDDO
[4778]	704
[4792]	705	ENDIF
[4778]	706
[4792]	707	RETURN
	708	END SUBROUTINE count_output_particles
[4778]	709
[4792]	710	!--------------------------------------------------------------------------------------------------!
	711	! Description:
	712	! ------------
	713	!
	714	!--------------------------------------------------------------------------------------------------!
	715	SUBROUTINE dop_read_output_particle_list( nr_particles_out )
[4778]	716
[4792]	717	IMPLICIT NONE
[4778]	718
[4792]	719	INTEGER(idp) :: dummy !<
	720	INTEGER(iwp) :: i !<
	721	INTEGER(iwp) :: istat !<
	722	INTEGER(iwp) :: iu !<
	723	INTEGER(iwp), INTENT(OUT) :: nr_particles_out
[4778]	724
	725
[4792]	726	iu = 345
	727	istat = 0
	728	nr_particles_out = 0
[4778]	729
[4792]	730	OPEN( UNIT=iu, FILE=TRIM( pts_id_file ) ) !kk should be changed to check_open
[4778]	731
[4792]	732	!
	733	!-- First stridem cout output particle
	734	DO WHILE( istat == 0 )
	735	READ( iu, *, iostat=istat ) dummy
	736	nr_particles_out = nr_particles_out + 1
	737	ENDDO
[4778]	738
[4792]	739	nr_particles_out = nr_particles_out - 1 ! subtract 1 for end of file read
[4778]	740
[4792]	741	ALLOCATE( part_id_list_file(nr_particles_out) )
[4778]	742
[4792]	743	REWIND( iu )
	744	!
	745	!-- Second stride, read particle ids for scheduled output particle.
	746	DO i = 1, nr_particles_out
	747	READ( iu, * ) part_id_list_file(i)
	748	ENDDO
[4778]	749
[4792]	750	CLOSE( iu )
[4778]	751
[4792]	752	END SUBROUTINE dop_read_output_particle_list
[4778]	753
[4792]	754	!--------------------------------------------------------------------------------------------------!
	755	! Description:
	756	! ------------
	757	!> Set output particle number for selected active particles
	758	!--------------------------------------------------------------------------------------------------!
	759	SUBROUTINE set_particle_number
[4778]	760
[4792]	761	IMPLICIT NONE
[4778]	762
[4792]	763	INTEGER(iwp) :: i !<
	764	INTEGER(iwp) :: j !<
	765	INTEGER(iwp) :: k !<
	766	INTEGER(iwp) :: n !<
	767	INTEGER(iwp) :: n_all !< count all particles for MOD function
	768	INTEGER(iwp) :: particle_nr !< output particle number
	769	INTEGER(iwp) :: pcount !< local particle count in case of pts_percentage
[4778]	770
[4792]	771	REAL(dp) :: fcount !< partical progress in %/100
	772	REAL(dp) :: finc !< increment of particle
[4778]	773
[4792]	774
	775	pcount = 0
	776	fcount = 0.0
	777
	778	particle_nr = start_local_numbering
	779	n_all = 0
	780	DO i = nxl, nxr
	781	DO j = nys, nyn
	782	DO k = nzb+1, nzt
	783	IF ( pts_increment > 1 ) THEN
	784	DO n = 1, prt_count(k,j,i)
	785	IF ( MOD( n_all, pts_increment ) == 0 ) THEN
	786	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
	787	particle_nr = particle_nr + 1
	788	ELSE
	789	grid_particles(k,j,i)%particles(n)%particle_nr = -2
	790	ENDIF
	791	n_all = n_all + 1
	792	ENDDO
	793	ELSEIF ( pts_percentage < 100.0_wp ) THEN
	794	finc = pts_percentage / 100
	795
	796	DO n = 1, prt_count(k,j,i)
[4778]	797	!
[4792]	798	!-- Eeach particle moves fraction on particle axis (i.e part percent == 80; move 0.8)
	799	!-- if increases next whole number, the particle is taken for output.
	800	fcount = fcount + finc
	801	IF ( pcount < INT( fcount ) ) THEN
	802	pcount = pcount + 1
	803	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
	804	particle_nr = particle_nr + 1
	805	ELSE
	806	grid_particles(k,j,i)%particles(n)%particle_nr = -2
	807	ENDIF
	808	ENDDO
	809	ELSE
	810	DO n = 1, prt_count(k,j,i)
	811	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
	812	particle_nr = particle_nr + 1
	813	ENDDO
	814	ENDIF
	815	ENDDO
	816	ENDDO
	817	ENDDO
[4778]	818
[4792]	819	RETURN
	820	END SUBROUTINE set_particle_number
[4778]	821
[4792]	822	!--------------------------------------------------------------------------------------------------!
	823	! Description:
	824	! ------------
	825	!
	826	!--------------------------------------------------------------------------------------------------!
	827	SUBROUTINE dop_find_particle_in_outlist
[4778]	828
[4792]	829	IMPLICIT NONE
	830
	831	INTEGER(iwp) :: i !<
[4778]	832	#if defined( __parallel )
[4792]	833	INTEGER(iwp) :: ierr !< MPI error code
[4778]	834	#endif
[4792]	835	INTEGER(iwp) :: j !<
	836	INTEGER(iwp) :: k !<
	837	INTEGER(iwp) :: l !<
	838	INTEGER(iwp) :: n !<
	839	INTEGER(iwp) :: nr_part !<
[4778]	840	! INTEGER, save :: icount=0
	841
	842
[4792]	843	nr_part = 0
	844
[4778]	845	!
[4792]	846	!-- If there is a long particle output list, for performance reason it may become necessary to
	847	!-- optimize the following loop.
[4778]	848	!
[4792]	849	!-- Decode the particle id in i,j,k,n.
	850	!-- Split serach, i.e search first in i, then in j ...
	851	DO i = nxl, nxr
	852	DO j = nys, nyn
	853	DO k = nzb+1, nzt
	854	DO n = 1, prt_count(k,j,i)
	855	DO l = 1, SIZE( part_id_list_file )
	856	IF ( grid_particles(k,j,i)%particles(n)%id == part_id_list_file(l) ) THEN
	857	grid_particles(k,j,i)%particles(n)%particle_nr = l
	858	nr_part = nr_part + 1
	859	ENDIF
	860	ENDDO
	861	ENDDO
	862	ENDDO
	863	ENDDO
	864	ENDDO
[4778]	865
	866	#if defined( __parallel )
[4792]	867	CALL MPI_ALLREDUCE( nr_part, initial_number_of_active_particles, 1, MPI_INTEGER, MPI_SUM, &
	868	comm2d, ierr )
[4778]	869	#else
[4792]	870	initial_number_of_active_particles = nr_part
[4778]	871	#endif
	872
[4792]	873	END SUBROUTINE dop_find_particle_in_outlist
[4778]	874
[4792]	875	!
[4778]	876	!-- Netcdf Setup
	877	!
[4792]	878	!--------------------------------------------------------------------------------------------------!
	879	! Description:
	880	! ------------
	881	!> Open NetCDF File DATA_1D_PTS_NETCDF
	882	!> Define Dimensions and variables
	883	!> Write constant variables
	884	!--------------------------------------------------------------------------------------------------!
	885	SUBROUTINE dop_netcdf_setup
[4778]	886
[4792]	887	IMPLICIT NONE
[4778]	888
[4792]	889	INTEGER, PARAMETER :: global_id_in_file = -1
[4778]	890
[4792]	891	INTEGER(iwp) :: i
	892	INTEGER(iwp) :: fix_ind
	893	INTEGER(iwp) :: return_value
	894	INTEGER(iwp) :: var_ind
[4778]	895
[4792]	896	INTEGER, DIMENSION(2) :: dimension_ids
[4778]	897
[4792]	898	LOGICAL :: const_flag
[4778]	899
	900
[4792]	901	nr_time_values = end_time / dt_dopts + 1 !kk has to be adapted to formular of 3d output
	902
	903	IF ( part_io%iam_io_pe ) THEN
	904	CALL netcdf4_init_module( "", part_io%comm_io, 0, 9, .TRUE., -1 )
	905
	906	file_name = 'DATA_1D_PTS_NETCDF'
[4778]	907	#if defined( __parallel )
[4792]	908	CALL netcdf4_open_file( 'parallel', TRIM( file_name ), file_id, return_value )
[4778]	909	#else
[4792]	910	CALL netcdf4_open_file( 'serial', TRIM( file_name ), file_id, return_value )
[4778]	911	#endif
[4792]	912
[4778]	913	!
[4792]	914	!-- Global attributes
	915	CALL netcdf4_write_attribute( 'parallel', file_id, global_id_in_file, 'comment', &
	916	'Particle ouput created by PALM module data_output_particle', &
	917	return_value=return_value )
[4778]	918
[4792]	919	CALL netcdf4_write_attribute( 'parallel', file_id, global_id_in_file, &
	920	'initial_nr_particles', &
	921	value_int32=initial_number_of_active_particles, &
	922	return_value=return_value )
[4778]	923	!
[4792]	924	!-- Define dimensions
	925	CALL netcdf4_init_dimension( 'parallel', file_id, did%prt, var_id%prt, 'prt','int32' , &
	926	nr_particles_out, .TRUE., return_value )
[4778]	927
[4792]	928	IF ( unlimited_dimension ) THEN
	929	CALL netcdf4_init_dimension( 'parallel', file_id, did%time, var_id%time, 'time','real32',&
	930	-1, .TRUE., return_value )
	931	ALLOCATE( time_axis_values(nr_time_values) )
	932	ELSE
	933	CALL netcdf4_init_dimension( 'parallel', file_id, did%time, var_id%time, 'time','real32',&
	934	nr_time_values, .TRUE., return_value )
	935	ENDIF
	936	ENDIF
[4778]	937	!
[4792]	938	!-- Variables without time axis
	939	!-- These variables will always be written only once at the beginning of the file
	940	dimension_ids(1) = did%prt
[4778]	941
[4792]	942	fix_ind = 1
	943	fix_variables(fix_ind)%name = 'origin_x'
	944	fix_variables(fix_ind)%units = 'meter'
[4778]	945
[4792]	946	IF ( part_io%iam_io_pe ) THEN
	947	CALL netcdf4_init_variable( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	948	fix_variables(fix_ind)%name, 'real32', dimension_ids(1:1), &
	949	.FALSE., return_value )
[4778]	950
[4792]	951	CALL netcdf4_write_attribute( 'parallel', file_id, fix_variables(fix_ind)%var_id, 'units', &
	952	value_char=TRIM( fix_variables(fix_ind)%units ), &
	953	return_value=return_value )
	954	ENDIF
[4778]	955
[4792]	956	fix_ind = fix_ind + 1
	957	fix_variables(fix_ind)%name = 'origin_y'
	958	fix_variables(fix_ind)%units = 'meter'
[4778]	959
[4792]	960	IF ( part_io%iam_io_pe ) THEN
	961	CALL netcdf4_init_variable( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	962	fix_variables(fix_ind)%name, 'real32', dimension_ids(1:1), &
	963	.FALSE., return_value )
[4778]	964
[4792]	965	CALL netcdf4_write_attribute( 'parallel', file_id, fix_variables(fix_ind)%var_id, 'units', &
	966	value_char=TRIM( fix_variables(fix_ind)%units ), &
	967	return_value=return_value )
[4778]	968
[4792]	969	ENDIF
[4778]	970
[4792]	971	fix_ind = fix_ind + 1
	972	fix_variables(fix_ind)%name = 'origin_z'
	973	fix_variables(fix_ind)%units = 'meter'
[4778]	974
[4792]	975	IF ( part_io%iam_io_pe ) THEN
	976	CALL netcdf4_init_variable( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	977	fix_variables(fix_ind)%name, 'real32', dimension_ids(1:1), &
	978	.FALSE., return_value )
[4778]	979
[4792]	980	CALL netcdf4_write_attribute( 'parallel', file_id, fix_variables(fix_ind)%var_id, 'units', &
	981	value_char=TRIM( fix_variables(fix_ind)%units ), &
	982	return_value=return_value )
	983	ENDIF
[4778]	984
	985	!
[4792]	986	!-- These variables are written if name end with _const'
	987	DO i = 1, SIZE( data_output_pts )
	988	const_flag = ( INDEX( TRIM( data_output_pts(i) ), '_const' ) > 0 )
	989	IF ( LEN( TRIM( data_output_pts(i) ) ) > 0 .AND. const_flag) THEN
	990	fix_ind = fix_ind + 1
	991	fix_variables(fix_ind)%name = TRIM( data_output_pts(i) )
[4778]	992
[4792]	993	SELECT CASE ( TRIM( fix_variables(fix_ind)%name ) )
	994	CASE ( 'radius_const' )
	995	fix_variables(fix_ind)%units = 'meter'
	996	fix_variables(fix_ind)%is_integer = .FALSE.
	997	CASE ( 'aux1_const' )
	998	fix_variables(fix_ind)%units = 'depend_on_setup'
	999	fix_variables(fix_ind)%is_integer = .FALSE.
	1000	CASE ( 'aux2_const' )
	1001	fix_variables(fix_ind)%units = 'depend_on_setup'
	1002	fix_variables(fix_ind)%is_integer = .FALSE.
	1003	CASE ( 'rvar1_const' )
	1004	fix_variables(fix_ind)%units = 'depend_on_setup'
	1005	fix_variables(fix_ind)%is_integer = .FALSE.
	1006	CASE ( 'rvar2_const' )
	1007	fix_variables(fix_ind)%units = 'depend_on_setup'
	1008	fix_variables(fix_ind)%is_integer = .FALSE.
	1009	CASE ( 'rvar3_const' )
	1010	fix_variables(fix_ind)%units = 'depend_on_setup'
	1011	fix_variables(fix_ind)%is_integer = .FALSE.
	1012	END SELECT
[4778]	1013
[4792]	1014	IF ( part_io%iam_io_pe ) THEN
	1015	IF ( fix_variables(fix_ind)%is_integer ) THEN
	1016	CALL netcdf4_init_variable( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	1017	fix_variables(fix_ind)%name, 'int32', &
	1018	dimension_ids(1:1), .FALSE., return_value )
	1019	ELSE
	1020	CALL netcdf4_init_variable( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	1021	fix_variables(fix_ind)%name, 'real32', &
	1022	dimension_ids(1:1), .FALSE., return_value )
	1023	ENDIF
[4778]	1024
[4792]	1025	CALL netcdf4_write_attribute( 'parallel', file_id, fix_variables(fix_ind)%var_id, &
	1026	'units', &
	1027	value_char=TRIM( fix_variables(fix_ind)%units ), &
	1028	return_value=return_value )
	1029	ENDIF
[4778]	1030
[4792]	1031	ENDIF
	1032	ENDDO
[4778]	1033
[4792]	1034	nr_fix_variables = fix_ind
[4778]	1035	!
[4792]	1036	!-- Variables time axis
	1037	!-- These variables will always be written in the time loop
	1038	dimension_ids(1) = did%prt
	1039	dimension_ids(2) = did%time
[4778]	1040
[4792]	1041	var_ind = 0
[4778]	1042
[4792]	1043	DO i = 1, SIZE( data_output_pts )
	1044	const_flag = ( INDEX( TRIM( data_output_pts(i) ), '_const' ) > 0 )
	1045	IF ( LEN( TRIM( data_output_pts(i) ) ) > 0 .AND. .NOT. const_flag ) THEN
	1046	var_ind = var_ind + 1
	1047	variables(var_ind)%name = TRIM( data_output_pts(i) )
[4778]	1048
[4792]	1049	SELECT CASE ( TRIM( variables(var_ind)%name) )
	1050	CASE ( 'id' )
	1051	variables(var_ind)%name = TRIM( data_output_pts(i) ) // '_low'
	1052	variables(var_ind)%units = 'Number'
	1053	variables(var_ind)%is_integer = .TRUE.
	1054	IF ( part_io%iam_io_pe ) THEN
	1055	CALL netcdf4_init_variable( 'parallel', file_id, variables(var_ind)%var_id, &
	1056	variables(var_ind)%name, 'int32', &
	1057	dimension_ids(1:2), .FALSE., return_value )
	1058	CALL netcdf4_write_attribute( 'parallel', file_id, variables(var_ind)%var_id, &
	1059	'units', &
	1060	value_char=TRIM( variables(var_ind)%units ), &
	1061	return_value=return_value )
	1062	ENDIF
[4778]	1063
[4792]	1064	var_ind = var_ind + 1
	1065	variables(var_ind)%name = TRIM( data_output_pts(i) ) // '_high'
	1066	variables(var_ind)%units = 'Number'
	1067	variables(var_ind)%is_integer = .TRUE.
	1068	CASE ( 'particle_nr' )
	1069	variables(var_ind)%units = 'Number'
	1070	variables(var_ind)%is_integer = .TRUE.
	1071	CASE ( 'class' )
	1072	variables(var_ind)%units = 'Number'
	1073	variables(var_ind)%is_integer = .TRUE.
	1074	CASE ( 'group' )
	1075	variables(var_ind)%units = 'Number'
	1076	variables(var_ind)%is_integer = .TRUE.
	1077	CASE ( 'x' )
	1078	variables(var_ind)%units = 'meter'
	1079	variables(var_ind)%is_integer = .FALSE.
	1080	CASE ( 'y' )
	1081	variables(var_ind)%units = 'meter'
	1082	variables(var_ind)%is_integer = .FALSE.
	1083	CASE ( 'z' )
	1084	variables(var_ind)%units = 'meter'
	1085	variables(var_ind)%is_integer = .FALSE.
	1086	CASE ( 'speed_x' )
	1087	variables(var_ind)%units = 'm/s'
	1088	variables(var_ind)%is_integer = .FALSE.
	1089	CASE ( 'speed_y' )
	1090	variables(var_ind)%units = 'm/s'
	1091	variables(var_ind)%is_integer = .FALSE.
	1092	CASE ( 'speed_z' )
	1093	variables(var_ind)%units = 'm/s'
	1094	variables(var_ind)%is_integer = .FALSE.
	1095	CASE ( 'radius' )
	1096	variables(var_ind)%units = 'meter'
	1097	variables(var_ind)%is_integer = .FALSE.
	1098	CASE ( 'age' )
	1099	variables(var_ind)%units = 'sec'
	1100	variables(var_ind)%is_integer = .FALSE.
	1101	CASE ( 'age_m' )
	1102	variables(var_ind)%units = 'sec'
	1103	variables(var_ind)%is_integer = .FALSE.
	1104	CASE ( 'dt_sum' )
	1105	variables(var_ind)%units = 'sec'
	1106	variables(var_ind)%is_integer = .FALSE.
	1107	CASE ( 'e_m' )
	1108	variables(var_ind)%units = 'Ws'
	1109	variables(var_ind)%is_integer = .FALSE.
	1110	CASE( 'weight_factor' )
	1111	variables(var_ind)%units = 'factor'
	1112	variables(var_ind)%is_integer = .FALSE.
	1113	CASE ( 'aux1' )
	1114	variables(var_ind)%units = 'depend_on_setup'
	1115	variables(var_ind)%is_integer = .FALSE.
	1116	CASE ( 'aux2' )
	1117	variables(var_ind)%units = 'depend_on_setup'
	1118	variables(var_ind)%is_integer = .FALSE.
	1119	CASE ( 'rvar1' )
	1120	variables(var_ind)%units = 'depend_on_setup'
	1121	variables(var_ind)%is_integer = .FALSE.
	1122	CASE ( 'rvar2' )
	1123	variables(var_ind)%units = 'depend_on_setup'
	1124	variables(var_ind)%is_integer = .FALSE.
	1125	CASE ( 'rvar3' )
	1126	variables(var_ind)%units = 'depend_on_setup'
	1127	variables(var_ind)%is_integer = .FALSE.
	1128	END SELECT
[4778]	1129
[4792]	1130	IF ( part_io%iam_io_pe ) THEN
	1131	IF ( variables(var_ind)%is_integer ) THEN
	1132	CALL netcdf4_init_variable( 'parallel', file_id, variables(var_ind)%var_id, &
	1133	variables(var_ind)%name, 'int32', dimension_ids(1:2), &
	1134	.FALSE., return_value )
	1135	ELSE
	1136	CALL netcdf4_init_variable( 'parallel', file_id, variables(var_ind)%var_id, &
	1137	variables(var_ind)%name, 'real32', dimension_ids(1:2), &
	1138	.FALSE., return_value )
	1139	ENDIF
[4778]	1140
[4792]	1141	CALL netcdf4_write_attribute( 'parallel', file_id, variables(var_ind)%var_id, 'units',&
	1142	value_char=TRIM( variables(var_ind)%units ), &
	1143	return_value=return_value )
	1144	ENDIF
[4778]	1145
[4792]	1146	ENDIF
	1147	ENDDO
[4778]	1148
[4792]	1149	nr_variables = var_ind
[4778]	1150
[4792]	1151	IF ( part_io%iam_io_pe ) THEN
	1152	CALL netcdf4_stop_file_header_definition( 'parallel', file_id, return_value )
	1153	ENDIF
[4778]	1154
[4792]	1155	CALL dop_write_axis
[4778]	1156
[4792]	1157	RETURN
[4778]	1158
[4792]	1159	CONTAINS
[4778]	1160
[4792]	1161	!--------------------------------------------------------------------------------------------------!
	1162	! Description:
	1163	! ------------
	1164	!
	1165	!--------------------------------------------------------------------------------------------------!
	1166	SUBROUTINE dop_write_axis
[4778]	1167
[4792]	1168	IMPLICIT NONE
[4778]	1169
[4792]	1170	INTEGER(iwp) :: i
	1171	INTEGER(iwp) :: return_value !< Return value data_output_netcdf4 .. routines
[4778]	1172
[4792]	1173	INTEGER,DIMENSION(1) :: bounds_origin, bounds_start, value_counts
[4778]	1174
[4792]	1175	INTEGER, POINTER, CONTIGUOUS, DIMENSION(:) :: prt_val
[4778]	1176
	1177
[4792]	1178	bounds_origin = 1
	1179	bounds_start(1) = 1
[4778]	1180
[4792]	1181	IF ( myid == 0 ) THEN
[4778]	1182
[4792]	1183	ALLOCATE( prt_val(nr_particles_out) )
	1184	DO i = 1, nr_particles_out
	1185	prt_val(i) = i
	1186	ENDDO
	1187	value_counts(1) = nr_particles_out
[4778]	1188
[4792]	1189	CALL netcdf4_write_variable( 'parallel', file_id, var_id%prt, bounds_start, &
	1190	value_counts, bounds_origin, .TRUE., &
	1191	values_int32_1d=prt_val, return_value=return_value)
[4778]	1192
[4792]	1193	DEALLOCATE( prt_val )
	1194	ENDIF
[4778]	1195
[4792]	1196	RETURN
	1197	END SUBROUTINE dop_write_axis
[4778]	1198
[4792]	1199	END SUBROUTINE dop_netcdf_setup
[4778]	1200
[4792]	1201	!--------------------------------------------------------------------------------------------------!
	1202	! Description:
	1203	! ------------
	1204	!> Write constant variables
	1205	!--------------------------------------------------------------------------------------------------!
	1206	SUBROUTINE dop_write_fixed_variables
[4778]	1207
[4792]	1208	IMPLICIT NONE
[4778]	1209
[4792]	1210	INTEGER(iwp) :: i !
	1211	INTEGER(iwp) :: return_value !
	1212
	1213	INTEGER(iwp),DIMENSION(1) :: bounds_origin, bounds_start, value_counts
	1214
	1215
	1216	bounds_origin(1) = 1
	1217	bounds_start(1) = io_start_index
	1218	value_counts(1) = io_end_index - io_start_index + 1
	1219
	1220
	1221	DO i = 1, nr_fix_variables
	1222
[4778]	1223	#if defined( __netcdf4 )
[4792]	1224	IF ( fix_variables(i)%is_integer ) THEN
	1225	out_buf_i = NF90_FILL_INT
	1226	ELSE
	1227	out_buf_r = NF90_FILL_REAL
	1228	ENDIF
[4778]	1229	#endif
	1230
[4792]	1231	CALL dop_fill_out_buf( fix_variables(i) )
[4778]	1232
[4792]	1233	CALL dop_get_remote_particle( fix_variables(i)%is_integer )
[4778]	1234
[4792]	1235	CALL part_io%sm_node_barrier( )
	1236	IF ( part_io%iam_io_pe ) THEN
	1237	IF ( fix_variables(i)%is_integer ) THEN
	1238	CALL netcdf4_write_variable( 'parallel', file_id, fix_variables(i)%var_id, &
	1239	bounds_start, value_counts, bounds_origin, .FALSE., &
	1240	values_int32_1d=out_buf_i, return_value=return_value)
	1241	ELSE
	1242	CALL netcdf4_write_variable( 'parallel', file_id, fix_variables(i)%var_id, &
	1243	bounds_start, value_counts, bounds_origin, .FALSE., &
	1244	values_real32_1d=out_buf_r, return_value=return_value)
	1245	ENDIF
	1246	ENDIF
	1247	CALL part_io%sm_node_barrier( )
	1248	ENDDO
[4778]	1249
[4792]	1250	RETURN
	1251	END SUBROUTINE dop_write_fixed_variables
[4778]	1252
[4792]	1253	!--------------------------------------------------------------------------------------------------!
	1254	! Description:
	1255	! ------------
	1256	!
	1257	!--------------------------------------------------------------------------------------------------!
	1258	SUBROUTINE dop_delete_particle_number
[4778]	1259
[4792]	1260	IMPLICIT NONE
[4778]	1261
[4792]	1262	INTEGER(iwp) :: i !<
	1263	INTEGER(iwp) :: j !<
	1264	INTEGER(iwp) :: k !<
	1265	INTEGER(iwp) :: n !<
	1266
[4778]	1267	!
[4792]	1268	!-- Delete inactive particles, i.e. all particles with particle_mask == .FALSE..
	1269	!-- Get an output particle nr of -1.
	1270	!-- kk Not sure if it is required here or already done in lagrangian_particle_model_mod before
	1271	!-- this call.
	1272	remote_nr_particles = 0
	1273	DO i = nxl, nxr
	1274	DO j = nys, nyn
	1275	DO k = nzb+1, nzt
	1276	DO n = 1, prt_count(k,j,i)
	1277	IF ( .NOT. grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1278	grid_particles(k,j,i)%particles(n)%particle_nr = -1
	1279	ENDIF
	1280	ENDDO
	1281	ENDDO
	1282	ENDDO
	1283	ENDDO
[4778]	1284
[4792]	1285	RETURN
	1286	END SUBROUTINE dop_delete_particle_number
[4778]	1287
[4792]	1288	!--------------------------------------------------------------------------------------------------!
	1289	! Description:
	1290	! ------------
	1291	!
	1292	!--------------------------------------------------------------------------------------------------!
	1293	SUBROUTINE dop_newly_generated_particles
[4778]	1294
[4792]	1295	IMPLICIT NONE
[4778]	1296
[4792]	1297	INTEGER(iwp) :: i !<
[4778]	1298	#if defined( __parallel )
[4792]	1299	INTEGER(iwp) :: ierr !< MPI error code
[4778]	1300	#endif
[4792]	1301	INTEGER(iwp) :: j !<
	1302	INTEGER(iwp) :: k !<
	1303	INTEGER(iwp) :: n !<
	1304	INTEGER(iwp) :: n_all !< count all particles for MOD function
	1305	INTEGER(iwp) :: nr_new_particle !<
	1306	INTEGER(iwp) :: particle_nr !<
	1307	INTEGER(iwp) :: start_new_numbering
[4778]	1308
[4792]	1309	INTEGER(iwp),DIMENSION(0:numprocs-1) :: nr_particles_new_r
	1310	INTEGER(iwp),DIMENSION(0:numprocs-1) :: nr_particles_new_s
[4778]	1311
[4792]	1312	REAL(dp) :: fcount
	1313	REAL(dp) :: finc
	1314
	1315
[4778]	1316	!
[4792]	1317	!-- Count Number of Newly Generated particles.
	1318	!-- Condition for a newparticle: particle_mask = .TRUE. and particle nr of -1.
[4778]	1319	!
[4792]	1320	!-- For performance reasons, this subroutine may be combined later with dop_delete_particle_number.
	1321	nr_new_particle = 0
[4778]	1322
[4792]	1323	IF ( pts_increment > 1 ) THEN
	1324	n_all = 0
	1325	DO i = nxl, nxr
	1326	DO j = nys, nyn
	1327	DO k = nzb+1, nzt
	1328	DO n = 1, prt_count(k,j,i)
	1329	IF ( grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1330	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1331	IF ( MOD( n_all, pts_increment ) == 0 ) THEN
	1332	nr_new_particle = nr_new_particle + 1
	1333	ENDIF
	1334	n_all = n_all + 1
	1335	ENDIF
	1336	ENDIF
	1337	ENDDO
	1338	ENDDO
	1339	ENDDO
	1340	ENDDO
	1341	ELSEIF ( pts_percentage < 100.0_wp ) THEN
	1342	finc = pts_percentage / 100
	1343	fcount = 0.0
[4778]	1344
[4792]	1345	DO i = nxl, nxr
	1346	DO j = nys, nyn
	1347	DO k = nzb+1, nzt
	1348	DO n = 1, prt_count(k,j,i)
	1349	IF ( grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1350	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1351	fcount = fcount + finc
	1352	IF ( nr_new_particle < INT( fcount ) ) THEN
	1353	nr_new_particle = nr_new_particle + 1
	1354	ENDIF
	1355	ENDIF
	1356	ENDIF
	1357	ENDDO
	1358	ENDDO
	1359	ENDDO
	1360	ENDDO
[4778]	1361
[4792]	1362	ELSE
	1363	DO i = nxl, nxr
	1364	DO j = nys, nyn
	1365	DO k = nzb+1, nzt
	1366	DO n = 1, prt_count(k,j,i)
	1367	IF ( grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1368	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1369	nr_new_particle = nr_new_particle + 1
	1370	ENDIF
	1371	ENDIF
	1372	ENDDO
	1373	ENDDO
	1374	ENDDO
	1375	ENDDO
	1376	ENDIF
[4778]	1377	!
[4792]	1378	!-- Determine start number of new particles on eac thread.
	1379	nr_particles_new_s = 0
	1380	nr_particles_new_s(myid) = nr_new_particle
[4778]	1381
	1382	#if defined( __parallel )
[4792]	1383	CALL MPI_ALLREDUCE( nr_particles_new_s, nr_particles_new_r, SIZE( nr_particles_new_s ), &
	1384	MPI_INTEGER, MPI_SUM, comm2d, ierr )
[4778]	1385	#else
[4792]	1386	nr_particles_new_r = nr_particles_new_s
[4778]	1387	#endif
	1388	!
[4792]	1389	!-- Abortion if selected particles from new particle set would exceed particle axis of output
	1390	!-- changed by JS.
	1391	IF ( ( SUM( nr_particles_new_r ) + initial_number_of_active_particles ) > nr_particles_out ) &
	1392	THEN
	1393	RETURN
	1394	ENDIF
[4778]	1395
[4792]	1396	start_new_numbering = initial_number_of_active_particles + 1
[4778]	1397
[4792]	1398	IF ( myid > 0) THEN
	1399	DO i = 1, numprocs-1
	1400	start_new_numbering = start_new_numbering + nr_particles_new_r(i-1)
	1401	IF ( myid == i ) EXIT
	1402	ENDDO
	1403	ENDIF
[4778]	1404
[4792]	1405	initial_number_of_active_particles = initial_number_of_active_particles + &
	1406	SUM( nr_particles_new_r )
[4778]	1407
[4792]	1408	dop_last_active_particle = initial_number_of_active_particles
[4778]	1409	!
[4792]	1410	!-- Set number of new particles
	1411	particle_nr = start_new_numbering
	1412	nr_new_particle = 0
[4778]	1413
[4792]	1414	IF ( pts_increment > 1 ) THEN
	1415	n_all = 0
	1416	DO i = nxl, nxr
	1417	DO j = nys, nyn
	1418	DO k = nzb+1, nzt
	1419	DO n = 1, prt_count(k,j,i)
	1420	IF ( grid_particles(k,j,i)%particles(n)%particle_mask) THEN
	1421	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1422	IF ( MOD( n_all, pts_increment ) == 0 ) THEN
	1423	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
	1424	particle_nr = particle_nr + 1
	1425	ELSE
	1426	grid_particles(k,j,i)%particles(n)%particle_nr = -2
	1427	ENDIF
	1428	n_all = n_all + 1
	1429	ENDIF
	1430	ENDIF
	1431	ENDDO
	1432	ENDDO
	1433	ENDDO
	1434	ENDDO
	1435	ELSEIF ( pts_percentage < 100.0_wp ) THEN
	1436	finc = pts_percentage / 100
	1437	fcount = 0.0_wp
[4778]	1438
[4792]	1439	DO i = nxl, nxr
	1440	DO j = nys, nyn
	1441	DO k = nzb+1, nzt
	1442	DO n = 1, prt_count(k,j,i)
	1443	IF ( grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1444	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1445	fcount = fcount + finc
	1446	IF ( nr_new_particle < INT( fcount ) ) THEN
[4778]	1447	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
[4792]	1448	particle_nr = particle_nr + 1
	1449	nr_new_particle = nr_new_particle + 1
	1450	ELSE
	1451	grid_particles(k,j,i)%particles(n)%particle_nr = -2
	1452	ENDIF
	1453	ENDIF
	1454	ENDIF
	1455	ENDDO
	1456	ENDDO
	1457	ENDDO
	1458	ENDDO
	1459	ELSE
	1460	DO i = nxl, nxr
	1461	DO j = nys, nyn
	1462	DO k = nzb+1, nzt
	1463	DO n = 1, prt_count(k,j,i)
	1464	IF ( grid_particles(k,j,i)%particles(n)%particle_mask ) THEN
	1465	IF ( grid_particles(k,j,i)%particles(n)%particle_nr == -1 ) THEN
	1466	grid_particles(k,j,i)%particles(n)%particle_nr = particle_nr
	1467	particle_nr = particle_nr + 1
	1468	ENDIF
	1469	ENDIF
	1470	ENDDO
	1471	ENDDO
	1472	ENDDO
	1473	ENDDO
[4778]	1474
	1475
[4792]	1476	ENDIF
[4778]	1477
	1478
	1479
[4792]	1480	RETURN
	1481	END SUBROUTINE dop_newly_generated_particles
[4778]	1482
[4792]	1483	!--------------------------------------------------------------------------------------------------!
	1484	! Description:
	1485	! ------------
	1486	!
	1487	!--------------------------------------------------------------------------------------------------!
	1488	SUBROUTINE dop_count_remote_particles
[4778]	1489
[4792]	1490	IMPLICIT NONE
	1491
[4778]	1492	#if defined( __parallel )
[4792]	1493	INTEGER(iwp) :: i !<
	1494	INTEGER(iwp) :: ierr !< MPI error code
	1495	INTEGER(iwp) :: j !<
	1496	INTEGER(iwp) :: k !<
	1497	INTEGER(iwp) :: n !<
	1498	INTEGER(iwp) :: iop !<
	1499	INTEGER(iwp) :: particle_nr
	1500	INTEGER(iwp) :: pe_nr
	1501	INTEGER(iwp) :: win_size
[4778]	1502
[4792]	1503	INTEGER(iwp), DIMENSION(0:numprocs-1) :: part_ind
[4778]	1504
	1505	!
[4792]	1506	!-- Count remote particles
	1507	remote_nr_particles = 0
	1508	DO i = nxl, nxr
	1509	DO j = nys, nyn
	1510	DO k = nzb+1, nzt
	1511	DO n = 1, prt_count(k,j,i)
	1512	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1513	IF ( particle_nr > 0 ) THEN
	1514	DO iop = 0, numprocs-1 !kk this loop has to be optimized
	1515	!
	1516	!-- Although the counting is local PE based, the following if is io processor
	1517	!-- based because particles in MPI shared memory do not have to be transfered.
	1518	IF ( particle_nr < io_start_index .OR. particle_nr > io_end_index ) THEN
	1519	IF ( particle_nr >= mo_indices(1,iop) .AND. &
	1520	particle_nr <= mo_indices(2,iop) ) THEN
	1521	remote_nr_particles(2,iop) = remote_nr_particles(2,iop) + 1
	1522	ENDIF
	1523	ENDIF
	1524	ENDDO
	1525	ENDIF
	1526	ENDDO
	1527	ENDDO
	1528	ENDDO
	1529	ENDDO
[4778]	1530
[4792]	1531	remote_nr_particles(1,0) = 0
	1532	DO i = 1, numprocs-1
	1533	remote_nr_particles(1,i) = remote_nr_particles(1,i-1) + remote_nr_particles(2,i-1)
	1534	ENDDO
[4778]	1535
[4792]	1536	win_size = SUM( remote_nr_particles(2,:) )
	1537	CALL dop_alloc_rma_mem( transfer_buffer_i, win_size, win_rma_buf_i )
	1538	CALL dop_alloc_rma_mem( transfer_buffer_r, win_size, win_rma_buf_r )
[4778]	1539
[4792]	1540	CALL MPI_ALLTOALL( remote_nr_particles, 2, MPI_INTEGER, rma_particles, 2, MPI_INTEGER, comm2d, &
	1541	ierr)
[4778]	1542
	1543	!
[4792]	1544	!-- The particles indices are the same for all output variables during one time step therefore, the
	1545	!-- indices are transfered only once here.
	1546	part_ind = remote_nr_particles(1,:)
	1547	transfer_buffer_i = -9999
[4778]	1548
[4792]	1549	DO i = nxl, nxr
	1550	DO j = nys, nyn
	1551	DO k = nzb+1, nzt
[4778]	1552
[4792]	1553	DO n = 1, prt_count(k,j,i)
	1554	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1555	IF ( particle_nr < io_start_index .OR. particle_nr > io_end_index ) THEN
	1556	IF ( particle_nr > 0 ) THEN
	1557	pe_nr = find_pe_from_particle_nr( particle_nr )
	1558	transfer_buffer_i(part_ind(pe_nr)) = particle_nr
	1559	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1560	ENDIF
	1561	ENDIF
	1562	ENDDO
	1563	ENDDO
	1564	ENDDO
	1565	ENDDO
[4778]	1566
[4792]	1567	CALL MPI_BARRIER( MPI_COMM_WORLD, ierr )
[4778]	1568
[4792]	1569	CALL dop_get_remote_indices
[4778]	1570
	1571	#endif
[4792]	1572	RETURN
	1573	END SUBROUTINE dop_count_remote_particles
[4778]	1574
[4792]	1575	!--------------------------------------------------------------------------------------------------!
	1576	! Description:
	1577	! ------------
	1578	!> Fill ouput buffer.
	1579	!> Local variables values are copied into output buffer. Local here means local to shared memory
	1580	!> group.
	1581	!> Remote variable values are copied into transfer buffer this is done by all threads.
	1582	!--------------------------------------------------------------------------------------------------!
	1583	SUBROUTINE dop_fill_out_buf (var)
[4778]	1584
[4792]	1585	IMPLICIT NONE
[4778]	1586
[4792]	1587	CHARACTER(LEN=32) :: local_name
[4778]	1588
[4792]	1589	INTEGER(iwp) :: i !<
	1590	INTEGER(iwp) :: j !<
	1591	INTEGER(iwp) :: k !<
	1592	INTEGER(iwp) :: local_len !<
	1593	INTEGER(iwp) :: n !<
	1594	INTEGER(iwp) :: particle_nr !<
	1595	INTEGER(iwp) :: pe_nr !<
	1596	INTEGER(idp) :: pval !<
[4778]	1597
[4792]	1598	INTEGER(iwp), DIMENSION(0:numprocs-1) :: part_ind
[4778]	1599
[4792]	1600	TYPE(var_def), INTENT(IN) :: var
	1601
	1602
	1603	part_ind = remote_nr_particles(1,:)
	1604	transfer_buffer_i = -9998
[4778]	1605	!
[4792]	1606	!-- Filling output buffer is the same for variable name and variable name_const, therefore set
	1607	!-- local_name without _const
	1608	local_len = INDEX( TRIM( var%name ), '_const' )
	1609	IF ( local_len == 0 ) THEN
	1610	local_name = var%name
	1611	ELSE
	1612	local_name = var%name(1:local_len-1)
	1613	ENDIF
[4778]	1614	!
[4792]	1615	!-- In this subroutine the particles are seperated:
	1616	!
	1617	!-- All particles which are located in the share memory area of the respective IO thread are copied
	1618	!-- into the output buffer. The other output particle are copied into the transfer buffer.
	1619	SELECT CASE ( TRIM( local_name ) )
	1620	CASE ( 'origin_x' )
	1621	DO i = nxl, nxr
	1622	DO j = nys, nyn
	1623	DO k = nzb+1, nzt
	1624	DO n =1, prt_count(k,j,i)
	1625	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1626	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1627	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%origin_x
	1628	ELSEIF ( particle_nr > 0 ) THEN
	1629	pe_nr = find_pe_from_particle_nr(particle_nr)
	1630	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1631	%particles(n)%origin_x
	1632	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1633	ENDIF
	1634	ENDDO
	1635	ENDDO
	1636	ENDDO
	1637	ENDDO
	1638	CASE ( 'origin_y' )
	1639	DO i = nxl, nxr
	1640	DO j = nys, nyn
	1641	DO k = nzb+1, nzt
	1642	DO n = 1, prt_count(k,j,i)
	1643	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1644	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1645	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%origin_y
	1646	ELSEIF ( particle_nr > 0 ) THEN
	1647	pe_nr = find_pe_from_particle_nr (particle_nr)
	1648	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1649	%particles(n)%origin_y
	1650	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1651	ENDIF
	1652	ENDDO
	1653	ENDDO
	1654	ENDDO
	1655	ENDDO
	1656	CASE ( 'origin_z' )
	1657	DO i = nxl, nxr
	1658	DO j = nys, nyn
	1659	DO k = nzb+1, nzt
	1660	DO n = 1, prt_count(k,j,i)
	1661	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1662	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1663	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%origin_z
	1664	ELSEIF ( particle_nr > 0 ) THEN
	1665	pe_nr = find_pe_from_particle_nr (particle_nr)
	1666	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1667	%particles(n)%origin_z
	1668	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1669	ENDIF
	1670	ENDDO
	1671	ENDDO
	1672	ENDDO
	1673	ENDDO
	1674	CASE ( 'id_low' )
	1675	DO i = nxl, nxr
	1676	DO j = nys, nyn
	1677	DO k = nzb+1, nzt
	1678	DO n = 1, prt_count(k,j,i)
	1679	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1680	pval = IBITS( grid_particles(k,j,i)%particles(n)%id,0,32 )
	1681	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1682	out_buf_i(particle_nr) = INT(pval,4)
	1683	ELSEIF ( particle_nr > 0 ) THEN
	1684	pe_nr = find_pe_from_particle_nr(particle_nr)
	1685	transfer_buffer_i(part_ind(pe_nr)) = INT( pval, 4 )
	1686	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1687	ENDIF
	1688	ENDDO
	1689	ENDDO
	1690	ENDDO
	1691	ENDDO
	1692	CASE ( 'id_high' )
	1693	DO i = nxl, nxr
	1694	DO j = nys, nyn
	1695	DO k = nzb+1, nzt
	1696	DO n = 1, prt_count(k,j,i)
	1697	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1698	pval = IBITS( grid_particles(k,j,i)%particles(n)%id,32,32 )
	1699	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1700	out_buf_i(particle_nr) = INT(pval,4)
	1701	ELSEIF ( particle_nr > 0 ) THEN
	1702	pe_nr = find_pe_from_particle_nr(particle_nr)
	1703	transfer_buffer_i(part_ind(pe_nr)) = INT( pval, 4 )
	1704	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1705	ENDIF
	1706	ENDDO
	1707	ENDDO
	1708	ENDDO
	1709	ENDDO
	1710	CASE ( 'particle_nr' )
	1711	DO i = nxl, nxr
	1712	DO j = nys, nyn
	1713	DO k = nzb+1, nzt
	1714	DO n = 1, prt_count(k,j,i)
	1715	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1716	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1717	out_buf_i(particle_nr) = grid_particles(k,j,i)%particles(n)%particle_nr
	1718	ELSEIF ( particle_nr > 0 ) THEN
	1719	pe_nr = find_pe_from_particle_nr(particle_nr)
	1720	transfer_buffer_i(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1721	%particles(n)%particle_nr
	1722	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1723	ENDIF
	1724	ENDDO
	1725	ENDDO
	1726	ENDDO
	1727	ENDDO
	1728	CASE ( 'class' )
	1729	DO i = nxl, nxr
	1730	DO j = nys, nyn
	1731	DO k = nzb+1, nzt
	1732	DO n = 1, prt_count(k,j,i)
	1733	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1734	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1735	out_buf_i(particle_nr) = grid_particles(k,j,i)%particles(n)%class
	1736	ELSEIF ( particle_nr > 0 ) THEN
	1737	pe_nr = find_pe_from_particle_nr(particle_nr)
	1738	transfer_buffer_i(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1739	%particles(n)%class
	1740	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1741	ENDIF
	1742	ENDDO
	1743	ENDDO
	1744	ENDDO
	1745	ENDDO
	1746	CASE ( 'group' )
	1747	DO i = nxl, nxr
	1748	DO j = nys, nyn
	1749	DO k = nzb+1, nzt
	1750	DO n = 1, prt_count(k,j,i)
	1751	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1752	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1753	out_buf_i(particle_nr) = grid_particles(k,j,i)%particles(n)%group
	1754	ELSEIF ( particle_nr > 0 ) THEN
	1755	pe_nr = find_pe_from_particle_nr(particle_nr)
	1756	transfer_buffer_i(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1757	%particles(n)%group
	1758	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1759	ENDIF
	1760	ENDDO
	1761	ENDDO
	1762	ENDDO
	1763	ENDDO
	1764	CASE ( 'x' )
	1765	DO i = nxl, nxr
	1766	DO j = nys, nyn
	1767	DO k = nzb+1, nzt
	1768	DO n = 1, prt_count(k,j,i)
	1769	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1770	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1771	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%x
	1772	ELSEIF ( particle_nr > 0 ) THEN
	1773	pe_nr = find_pe_from_particle_nr(particle_nr)
	1774	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%x
	1775	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1776	ENDIF
	1777	ENDDO
	1778	ENDDO
	1779	ENDDO
	1780	ENDDO
	1781	CASE ( 'y' )
	1782	DO i = nxl, nxr
	1783	DO j = nys, nyn
	1784	DO k = nzb+1, nzt
	1785	DO n = 1, prt_count(k,j,i)
	1786	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1787	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1788	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%y
	1789	ELSEIF ( particle_nr > 0 ) THEN
	1790	pe_nr = find_pe_from_particle_nr(particle_nr)
	1791	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%y
	1792	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1793	ENDIF
	1794	ENDDO
	1795	ENDDO
	1796	ENDDO
	1797	ENDDO
	1798	CASE ( 'z' )
	1799	DO i = nxl, nxr
	1800	DO j = nys, nyn
	1801	DO k = nzb+1, nzt
	1802	DO n = 1, prt_count(k,j,i)
	1803	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1804	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1805	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%z
	1806	ELSEIF ( particle_nr > 0 ) THEN
	1807	pe_nr = find_pe_from_particle_nr(particle_nr)
	1808	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%z
	1809	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1810	ENDIF
	1811	ENDDO
	1812	ENDDO
	1813	ENDDO
	1814	ENDDO
	1815	CASE ( 'speed_x' )
	1816	DO i = nxl, nxr
	1817	DO j = nys, nyn
	1818	DO k = nzb+1, nzt
	1819	DO n = 1, prt_count(k,j,i)
	1820	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1821	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1822	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%speed_x
	1823	ELSEIF ( particle_nr > 0 ) THEN
	1824	pe_nr = find_pe_from_particle_nr(particle_nr)
	1825	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1826	%particles(n)%speed_x
	1827	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1828	ENDIF
	1829	ENDDO
	1830	ENDDO
	1831	ENDDO
	1832	ENDDO
	1833	CASE ( 'speed_y' )
	1834	DO i = nxl, nxr
	1835	DO j = nys, nyn
	1836	DO k = nzb+1, nzt
	1837	DO n = 1, prt_count(k,j,i)
	1838	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1839	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1840	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%speed_y
	1841	ELSEIF ( particle_nr > 0 ) THEN
	1842	pe_nr = find_pe_from_particle_nr(particle_nr)
	1843	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1844	%particles(n)%speed_y
	1845	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1846	ENDIF
	1847	ENDDO
	1848	ENDDO
	1849	ENDDO
	1850	ENDDO
	1851	CASE ( 'speed_z' )
	1852	DO i = nxl, nxr
	1853	DO j = nys, nyn
	1854	DO k = nzb+1, nzt
	1855	DO n = 1, prt_count(k,j,i)
	1856	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1857	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1858	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%speed_z
	1859	ELSEIF ( particle_nr > 0 ) THEN
	1860	pe_nr = find_pe_from_particle_nr (particle_nr)
	1861	transfer_buffer_r (part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%speed_z
	1862	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1863	ENDIF
	1864	ENDDO
	1865	ENDDO
	1866	ENDDO
	1867	ENDDO
	1868	CASE ( 'radius' )
	1869	DO i=nxl,nxr
	1870	DO j=nys,nyn
	1871	DO k=nzb+1,nzt
	1872	DO n=1,prt_count(k,j,i)
	1873	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1874	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1875	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%radius
	1876	ELSEIF ( particle_nr > 0 ) THEN
	1877	pe_nr = find_pe_from_particle_nr(particle_nr)
	1878	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1879	%particles(n)%radius
	1880	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1881	ENDIF
	1882	ENDDO
	1883	ENDDO
	1884	ENDDO
	1885	ENDDO
	1886	CASE ( 'age' )
	1887	DO i = nxl, nxr
	1888	DO j = nys, nyn
	1889	DO k = nzb+1, nzt
	1890	DO n = 1, prt_count(k,j,i)
	1891	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1892	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1893	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%age
	1894	ELSEIF ( particle_nr > 0 ) THEN
	1895	pe_nr = find_pe_from_particle_nr(particle_nr)
	1896	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%age
	1897	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1898	ENDIF
	1899	ENDDO
	1900	ENDDO
	1901	ENDDO
	1902	ENDDO
	1903	CASE ( 'age_m' )
	1904	DO i = nxl, nxr
	1905	DO j = nys, nyn
	1906	DO k = nzb+1, nzt
	1907	DO n = 1, prt_count(k,j,i)
	1908	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1909	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1910	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%age_m
	1911	ELSEIF ( particle_nr > 0 ) THEN
	1912	pe_nr = find_pe_from_particle_nr(particle_nr)
	1913	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1914	%particles(n)%age_m
	1915	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1916	ENDIF
	1917	ENDDO
	1918	ENDDO
	1919	ENDDO
	1920	ENDDO
	1921	CASE ( 'dt_sum' )
	1922	DO i = nxl, nxr
	1923	DO j = nys, nyn
	1924	DO k = nzb+1, nzt
	1925	DO n = 1, prt_count(k,j,i)
	1926	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1927	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1928	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%dt_sum
	1929	ELSEIF ( particle_nr > 0 ) THEN
	1930	pe_nr = find_pe_from_particle_nr(particle_nr)
	1931	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1932	%particles(n)%dt_sum
	1933	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1934	ENDIF
	1935	ENDDO
	1936	ENDDO
	1937	ENDDO
	1938	ENDDO
	1939	CASE( 'e_m' )
	1940	DO i = nxl, nxr
	1941	DO j = nys, nyn
	1942	DO k = nzb+1, nzt
	1943	DO n = 1, prt_count(k,j,i)
	1944	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1945	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1946	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%e_m
	1947	ELSEIF ( particle_nr > 0 ) THEN
	1948	pe_nr = find_pe_from_particle_nr(particle_nr)
	1949	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i)%particles(n)%e_m
	1950	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1951	ENDIF
	1952	ENDDO
	1953	ENDDO
	1954	ENDDO
	1955	ENDDO
	1956	CASE ( 'weight_factor' )
	1957	DO i = nxl, nxr
	1958	DO j = nys, nyn
	1959	DO k = nzb+1, nzt
	1960	DO n = 1, prt_count(k,j,i)
	1961	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1962	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1963	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%weight_factor
	1964	ELSEIF ( particle_nr > 0 ) THEN
	1965	pe_nr = find_pe_from_particle_nr(particle_nr)
	1966	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1967	%particles(n)%weight_factor
	1968	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1969	ENDIF
	1970	ENDDO
	1971	ENDDO
	1972	ENDDO
	1973	ENDDO
	1974	CASE ( 'aux1' )
	1975	DO i = nxl, nxr
	1976	DO j = nys, nyn
	1977	DO k = nzb+1, nzt
	1978	DO n = 1, prt_count(k,j,i)
	1979	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1980	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1981	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%aux1
	1982	ELSEIF ( particle_nr > 0 ) THEN
	1983	pe_nr = find_pe_from_particle_nr(particle_nr)
	1984	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	1985	%particles(n)%aux1
	1986	part_ind(pe_nr) = part_ind(pe_nr) + 1
	1987	ENDIF
	1988	ENDDO
	1989	ENDDO
	1990	ENDDO
	1991	ENDDO
	1992	CASE ( 'aux2' )
	1993	DO i = nxl, nxr
	1994	DO j = nys, nyn
	1995	DO k = nzb+1, nzt
	1996	DO n = 1, prt_count(k,j,i)
	1997	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	1998	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	1999	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%aux2
	2000	ELSEIF ( particle_nr > 0 ) THEN
	2001	pe_nr = find_pe_from_particle_nr(particle_nr)
	2002	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	2003	%particles(n)%aux2
	2004	part_ind(pe_nr) = part_ind(pe_nr) + 1
	2005	ENDIF
	2006	ENDDO
	2007	ENDDO
	2008	ENDDO
	2009	ENDDO
	2010	CASE ( 'rvar1' )
	2011	DO i = nxl, nxr
	2012	DO j = nys, nyn
	2013	DO k = nzb+1, nzt
	2014	DO n = 1, prt_count(k,j,i)
	2015	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	2016	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	2017	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%rvar1
	2018	ELSEIF ( particle_nr > 0 ) THEN
	2019	pe_nr = find_pe_from_particle_nr(particle_nr)
	2020	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	2021	%particles(n)%rvar1
	2022	part_ind(pe_nr) = part_ind(pe_nr) + 1
	2023	ENDIF
	2024	ENDDO
	2025	ENDDO
	2026	ENDDO
	2027	ENDDO
	2028	CASE ( 'rvar2' )
	2029	DO i = nxl, nxr
	2030	DO j = nys, nyn
	2031	DO k = nzb+1, nzt
	2032	DO n = 1, prt_count(k,j,i)
	2033	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	2034	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	2035	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%rvar2
	2036	ELSEIF ( particle_nr > 0 ) THEN
	2037	pe_nr = find_pe_from_particle_nr (particle_nr)
	2038	transfer_buffer_r (part_ind(pe_nr)) = grid_particles(k,j,i) &
	2039	%particles(n)%rvar2
	2040	part_ind(pe_nr) = part_ind(pe_nr) + 1
	2041	ENDIF
	2042	ENDDO
	2043	ENDDO
	2044	ENDDO
	2045	ENDDO
	2046	CASE ( 'rvar3' )
	2047	DO i = nxl, nxr
	2048	DO j = nys, nyn
	2049	DO k = nzb+1, nzt
	2050	DO n = 1, prt_count(k,j,i)
	2051	particle_nr = grid_particles(k,j,i)%particles(n)%particle_nr
	2052	IF ( particle_nr >= io_start_index .AND. particle_nr <= io_end_index ) THEN
	2053	out_buf_r(particle_nr) = grid_particles(k,j,i)%particles(n)%rvar3
	2054	ELSEIF ( particle_nr > 0 ) THEN
	2055	pe_nr = find_pe_from_particle_nr(particle_nr)
	2056	transfer_buffer_r(part_ind(pe_nr)) = grid_particles(k,j,i) &
	2057	%particles(n)%rvar3
	2058	part_ind(pe_nr) = part_ind(pe_nr) + 1
	2059	ENDIF
	2060	ENDDO
	2061	ENDDO
	2062	ENDDO
	2063	ENDDO
	2064	END SELECT
[4778]	2065
[4792]	2066	RETURN
	2067	END SUBROUTINE dop_fill_out_buf
[4778]	2068
	2069	#if defined( __parallel )
	2070
[4792]	2071	!--------------------------------------------------------------------------------------------------!
	2072	! Description:
	2073	! ------------
	2074	!> Get indices (displacement) of remot particles
	2075	!--------------------------------------------------------------------------------------------------!
	2076	SUBROUTINE dop_get_remote_indices
[4778]	2077
[4792]	2078	IMPLICIT NONE
[4778]	2079
[4792]	2080	INTEGER(iwp) :: bufsize !< size of remote indices array
	2081	INTEGER(iwp) :: i !<
	2082	INTEGER(iwp) :: ierr !< MPI error code
	2083	INTEGER(iwp) :: ind_local !< index in remore indices array
	2084	INTEGER(KIND=MPI_ADDRESS_KIND) :: disp !< displacement in RMA window
[4778]	2085
	2086
[4792]	2087	bufsize = SUM( rma_particles(2,:) )
	2088	ALLOCATE( remote_indices(0:bufsize) )
	2089	remote_indices = -1
[4778]	2090
[4792]	2091	ind_local = 0
	2092	CALL MPI_WIN_FENCE( 0, win_rma_buf_i, ierr )
	2093	DO i = 0, numprocs-1
	2094	IF ( rma_particles(2,i) > 0 ) THEN
	2095	disp = rma_particles(1,i)
	2096	IF ( rma_particles(2,i) > 0 ) THEN
	2097	CALL MPI_GET( remote_indices(ind_local), rma_particles(2,i), MPI_INTEGER, i, disp, &
	2098	rma_particles(2,i), MPI_INTEGER, win_rma_buf_i, ierr )
	2099	ind_local = ind_local + rma_particles(2,i)
	2100	ENDIF
	2101	ENDIF
	2102	ENDDO
	2103	CALL MPI_WIN_FENCE( 0, win_rma_buf_i, ierr )
	2104
	2105	RETURN
	2106	END SUBROUTINE dop_get_remote_indices
[4778]	2107	#endif
	2108
[4792]	2109	!--------------------------------------------------------------------------------------------------!
	2110	! Description:
	2111	! ------------
	2112	!--------------------------------------------------------------------------------------------------!
	2113	SUBROUTINE dop_get_remote_particle (is_integer)
[4778]	2114
[4792]	2115	IMPLICIT NONE
[4778]	2116
[4792]	2117	LOGICAL, INTENT(IN) :: is_integer
[4778]	2118
	2119
	2120	#if defined( __parallel )
[4792]	2121	INTEGER(iwp) :: bufsize !< size of remote data array
	2122	INTEGER(iwp) :: i !<
	2123	INTEGER(iwp) :: ierr !< MPI error code
	2124	INTEGER(iwp) :: ind_local !< index in remore indices array
	2125	INTEGER(iwp) :: j !<
	2126	INTEGER(iwp) :: particle_nr !< particle number
	2127	INTEGER(KIND=MPI_ADDRESS_KIND) :: disp !< displacement in RMA window
[4778]	2128
[4792]	2129	INTEGER(iwp), ALLOCATABLE, DIMENSION(:) :: rma_buf_i !< buffer to receive remote data (INTEGER)
[4778]	2130
[4792]	2131	REAL(sp), ALLOCATABLE, DIMENSION(:) :: rma_buf_r !< buffer to receive remote data (REAL)
[4778]	2132
	2133
[4792]	2134	bufsize = SUM( rma_particles(2,:) )
	2135	ind_local = 0
	2136	ALLOCATE( rma_buf_r(0:bufsize-1) )
	2137	ALLOCATE( rma_buf_i(0:bufsize-1) )
	2138
	2139	IF ( is_integer ) THEN
	2140	CALL MPI_WIN_FENCE( 0, win_rma_buf_i, ierr )
	2141	ELSE
	2142	CALL MPI_WIN_FENCE( 0, win_rma_buf_r, ierr )
	2143	ENDIF
	2144	DO i = 0, numprocs-1
	2145	IF ( rma_particles(2,i) > 0 ) THEN
	2146	IF ( is_integer ) THEN
	2147	disp = rma_particles(1,i)
	2148	CALL MPI_GET( rma_buf_i(ind_local), rma_particles(2,i), MPI_INTEGER, i, disp, &
	2149	rma_particles(2,i), MPI_INTEGER, win_rma_buf_i, ierr )
	2150	ind_local = ind_local + rma_particles(2,i)
	2151	ELSE
	2152	disp = rma_particles(1,i)
	2153	CALL MPI_GET( rma_buf_r(ind_local), rma_particles(2,i), MPI_real, i, disp, &
	2154	rma_particles(2,i), MPI_real, win_rma_buf_r, ierr )
	2155	ind_local = ind_local + rma_particles(2,i)
	2156	ENDIF
	2157	ENDIF
	2158	ENDDO
	2159	IF ( is_integer ) THEN
	2160	CALL MPI_WIN_FENCE( 0, win_rma_buf_i, ierr )
	2161	ELSE
	2162	CALL MPI_WIN_FENCE( 0, win_rma_buf_r, ierr )
	2163	ENDIF
	2164
	2165	ind_local = 0
	2166
	2167	DO i = 0, numprocs-1
	2168	IF ( rma_particles(2,i) > 0 ) THEN
	2169	IF ( is_integer ) THEN
[4778]	2170	!
[4792]	2171	!-- Copy data from remote PEs into output array
	2172	DO j = 0, rma_particles(2,i)-1
	2173	particle_nr = remote_indices(ind_local)
	2174	out_buf_i(particle_nr) = rma_buf_i(ind_local)
	2175	ind_local = ind_local + 1
	2176	ENDDO
	2177	ELSE
[4778]	2178	!
[4792]	2179	!-- Copy data from remote PEs into output array
	2180	DO j = 0, rma_particles(2,i)-1
	2181	particle_nr = remote_indices(ind_local)
	2182	out_buf_r(particle_nr) = rma_buf_r(ind_local)
	2183	ind_local = ind_local + 1
	2184	ENDDO
	2185	ENDIF
	2186	ENDIF
	2187	ENDDO
[4778]	2188
[4792]	2189	IF ( ALLOCATED( rma_buf_r) ) DEALLOCATE( rma_buf_r )
	2190	IF ( ALLOCATED( rma_buf_i) ) DEALLOCATE( rma_buf_i )
[4778]	2191	#else
[4792]	2192	IF ( is_integer ) THEN
[4778]	2193	ENDIF
	2194	#endif
	2195
[4792]	2196	RETURN
	2197	END SUBROUTINE dop_get_remote_particle
[4778]	2198
	2199	#if defined( __parallel )
[4792]	2200	!--------------------------------------------------------------------------------------------------!
	2201	! Description:
	2202	! ------------
	2203	!> Allocate memory and cread window for one-sided communication (INTEGER 1-D array)
	2204	!--------------------------------------------------------------------------------------------------!
	2205	SUBROUTINE dop_alloc_rma_mem_i1( array, idim1, win )
[4778]	2206
[4792]	2207	IMPLICIT NONE
[4778]	2208
[4792]	2209	INTEGER(iwp), INTENT(IN) :: idim1 !<
	2210	INTEGER :: ierr !< MPI error code
	2211	INTEGER(iwp), INTENT(OUT) :: win !<
	2212	INTEGER(KIND=MPI_ADDRESS_KIND) :: winsize !< size of RMA window
[4778]	2213
[4792]	2214	INTEGER(isp), DIMENSION(:), POINTER, INTENT(INOUT) :: array !<
[4778]	2215
	2216
[4792]	2217	winsize = MAX( idim1, 2 )
[4778]	2218
[4792]	2219	ALLOCATE( array(0:winsize-1) )
[4778]	2220
[4792]	2221	winsize = winsize * isp
[4778]	2222
[4792]	2223	CALL MPI_WIN_CREATE( array, winsize, isp, MPI_INFO_NULL, comm2d, win, ierr )
[4778]	2224
[4792]	2225	array = -1
	2226
	2227	CALL MPI_WIN_FENCE( 0, win, ierr )
	2228
	2229	END SUBROUTINE dop_alloc_rma_mem_i1
[4778]	2230	#endif
	2231
	2232	#if defined( __parallel )
[4792]	2233	!--------------------------------------------------------------------------------------------------!
	2234	! Description:
	2235	! ------------
	2236	!> Allocate memory and cread window for one-sided communication (REAL 1-D array)
	2237	!--------------------------------------------------------------------------------------------------!
	2238	SUBROUTINE dop_alloc_rma_mem_r1( array, idim1, win )
[4778]	2239
[4792]	2240	IMPLICIT NONE
[4778]	2241
[4792]	2242	INTEGER(iwp), INTENT(IN) :: idim1 !<
	2243	INTEGER :: ierr !< MPI error code
	2244	INTEGER(iwp), INTENT(OUT) :: win !<
	2245	INTEGER(KIND=MPI_ADDRESS_KIND) :: winsize !< size of RMA window
[4778]	2246
[4792]	2247	REAL(sp), DIMENSION(:), POINTER, INTENT(INOUT) :: array !<
[4778]	2248
	2249
[4792]	2250	winsize = MAX( idim1, 2 )
[4778]	2251
[4792]	2252	ALLOCATE( array(0:winsize-1) )
[4778]	2253
[4792]	2254	winsize = winsize * sp
[4778]	2255
[4792]	2256	CALL MPI_WIN_CREATE( array, winsize, sp, MPI_INFO_NULL, comm2d, win, ierr )
[4778]	2257
[4792]	2258	array = -1.0_wp
[4778]	2259
[4792]	2260	CALL MPI_WIN_FENCE( 0, win, ierr )
[4778]	2261
[4792]	2262	END SUBROUTINE dop_alloc_rma_mem_r1
[4778]	2263	#endif
	2264
[4792]	2265	!--------------------------------------------------------------------------------------------------!
	2266	! Description:
	2267	! ------------
	2268	!--------------------------------------------------------------------------------------------------!
	2269	SUBROUTINE deallocate_and_free
[4778]	2270
[4792]	2271	IMPLICIT NONE
[4778]	2272
	2273	#if defined( __parallel )
[4792]	2274	INTEGER :: ierr !< MPI error code
[4778]	2275	#endif
	2276
	2277	#if defined( __parallel )
[4792]	2278	CALL MPI_WIN_FREE( win_rma_buf_i, ierr )
	2279	CALL MPI_WIN_FREE( win_rma_buf_r, ierr )
[4778]	2280	#endif
[4792]	2281	IF ( ALLOCATED( remote_indices ) ) DEALLOCATE( remote_indices )
[4778]	2282
[4792]	2283	DEALLOCATE( transfer_buffer_i )
	2284	DEALLOCATE( transfer_buffer_r )
[4778]	2285
[4792]	2286	RETURN
[4778]	2287
[4792]	2288	END SUBROUTINE deallocate_and_free
[4778]	2289
	2290
[4792]	2291	FUNCTION find_pe_from_particle_nr( particle_nr ) RESULT( pe_nr )
	2292	IMPLICIT NONE
[4778]	2293
[4792]	2294	INTEGER(iwp) :: base !<
	2295	INTEGER(iwp), INTENT(IN) :: particle_nr
	2296	INTEGER(iwp) :: pe_nr !<
	2297	INTEGER(iwp) :: pnr !<
[4778]	2298
[4792]	2299	IF ( irregular_distribubtion ) THEN
	2300	IF ( particle_nr <= nr_particles_rest * nr_particles_pe ) THEN
	2301	pe_nr = ( particle_nr - 1 ) / nr_particles_pe
	2302	ELSE
	2303	base = nr_particles_rest * nr_particles_pe
	2304	pnr = particle_nr - base
	2305	pe_nr = ( pnr - 1 ) / ( nr_particles_pe - 1 )
	2306	pe_nr = pe_nr + nr_particles_rest
	2307	ENDIF
	2308	ELSE
	2309	pe_nr = ( particle_nr - 1 ) / nr_particles_pe
	2310	ENDIF
[4778]	2311
	2312
[4792]	2313	!-- kk This error test is to detect programming errors. For performance reasons it can be removed
	2314	!-- kk in the final, stable version.
[4778]	2315
[4792]	2316	END FUNCTION find_pe_from_particle_nr
	2317
	2318	END MODULE data_output_particle_mod

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source: palm/trunk/SOURCE/data_output_particle_mod.f90 @ 4838

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