!> @file init_dvrp.f90 !------------------------------------------------------------------------------! ! This file is part of PALM. ! ! PALM is free software: you can redistribute it and/or modify it under the ! terms of the GNU General Public License as published by the Free Software ! Foundation, either version 3 of the License, or (at your option) any later ! version. ! ! PALM is distributed in the hope that it will be useful, but WITHOUT ANY ! WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR ! A PARTICULAR PURPOSE. See the GNU General Public License for more details. ! ! You should have received a copy of the GNU General Public License along with ! PALM. If not, see . ! ! Copyright 1997-2017 Leibniz Universitaet Hannover !------------------------------------------------------------------------------! ! ! Current revisions: ! ----------------- ! ! ! Former revisions: ! ----------------- ! $Id: init_dvrp.f90 2101 2017-01-05 16:42:31Z lvollmer $ ! ! 2000 2016-08-20 18:09:15Z knoop ! Forced header and separation lines into 80 columns ! ! 1808 2016-04-05 19:44:00Z raasch ! routine local_getenv replaced by standard FORTRAN routine ! ! 1682 2015-10-07 23:56:08Z knoop ! Code annotations made doxygen readable ! ! 1353 2014-04-08 15:21:23Z heinze ! REAL constants provided with KIND-attribute ! ! 1322 2014-03-20 16:38:49Z raasch ! REAL constants defined as wp-kind ! ! 1320 2014-03-20 08:40:49Z raasch ! ONLY-attribute added to USE-statements, ! kind-parameters added to all INTEGER and REAL declaration statements, ! kinds are defined in new module kinds, ! revision history before 2012 removed, ! comment fields (!:) to be used for variable explanations added to ! all variable declaration statements ! ! 1036 2012-10-22 13:43:42Z raasch ! code put under GPL (PALM 3.9) ! ! Revision 1.1 2000/04/27 06:24:39 raasch ! Initial revision ! ! ! Description: ! ------------ !> Initializing actions needed when using dvrp-software !------------------------------------------------------------------------------! SUBROUTINE init_dvrp #if defined( __dvrp_graphics ) USE arrays_3d, & ONLY: zu USE DVRP USE dvrp_variables USE grid_variables, & ONLY: dx, dy USE indices, & ONLY: nx, nxl, nxr, ny, nyn, nys, nzb, nzb_s_inner USE kinds USE pegrid USE control_parameters, & ONLY: message_string, nz_do3d, run_identifier, topography IMPLICIT NONE CHARACTER (LEN=2) :: section_chr !< CHARACTER (LEN=3) :: prefix_chr !< CHARACTER (LEN=80) :: dvrp_file_local !< INTEGER(iwp) :: cluster_mode !< INTEGER(iwp) :: cluster_size_x !< INTEGER(iwp) :: cluster_size_y !< INTEGER(iwp) :: cluster_size_z !< INTEGER(iwp) :: gradient_normals !< INTEGER(iwp) :: i !< INTEGER(iwp) :: j !< INTEGER(iwp) :: k !< INTEGER(iwp) :: l !< INTEGER(iwp) :: m !< INTEGER(iwp) :: nx_dvrp_l !< INTEGER(iwp) :: nx_dvrp_r !< INTEGER(iwp) :: ny_dvrp_n !< INTEGER(iwp) :: ny_dvrp_s !< INTEGER(iwp) :: pn !< INTEGER(iwp) :: tv !< INTEGER(iwp) :: vn !< LOGICAL :: allocated !< REAL(sp) :: center(3) !< REAL(sp) :: cluster_alpha !< REAL(sp) :: distance !< REAL(sp) :: tmp_b !< REAL(sp) :: tmp_g !< REAL(sp) :: tmp_r !< REAL(sp) :: tmp_t !< REAL(sp) :: tmp_th !< REAL(sp) :: tmp_thr !< REAL(sp) :: tmp_x1 !< REAL(sp) :: tmp_x2 !< REAL(sp) :: tmp_y1 !< REAL(sp) :: tmp_y2 !< REAL(sp) :: tmp_z1 !< REAL(sp) :: tmp_z2 !< REAL(sp) :: tmp_1 !< REAL(sp) :: tmp_2 !< REAL(sp) :: tmp_3 !< REAL(sp) :: tmp_4 !< REAL(sp) :: tmp_5 !< REAL(sp) :: tmp_6 !< REAL(sp) :: tmp_7 !< REAL(sp), DIMENSION(:,:,:), ALLOCATABLE :: local_pf !< TYPE(CSTRING), SAVE :: dvrp_directory_c !< TYPE(CSTRING), SAVE :: dvrp_file_c !< TYPE(CSTRING), SAVE :: dvrp_file_local_c !< TYPE(CSTRING), SAVE :: dvrp_host_c !< TYPE(CSTRING), SAVE :: dvrp_password_c !< TYPE(CSTRING), SAVE :: dvrp_username_c !< TYPE(CSTRING), SAVE :: name_c !< ! !-- Set clipping to default (total domain), if not set by user IF ( clip_dvrp_l == 9999999.9_wp ) clip_dvrp_l = 0.0_wp IF ( clip_dvrp_r == 9999999.9_wp ) clip_dvrp_r = ( nx + 1 ) * dx IF ( clip_dvrp_s == 9999999.9_wp ) clip_dvrp_s = 0.0_wp IF ( clip_dvrp_n == 9999999.9_wp ) clip_dvrp_n = ( ny + 1 ) * dy ! !-- Calculate the clipping index limits nx_dvrp_l = clip_dvrp_l / dx nx_dvrp_r = clip_dvrp_r / dx ny_dvrp_s = clip_dvrp_s / dy ny_dvrp_n = clip_dvrp_n / dy IF ( nx_dvrp_l < nxr .AND. nx_dvrp_r > nxl .AND. & ny_dvrp_s < nyn .AND. ny_dvrp_n > nys ) THEN dvrp_overlap = .TRUE. nxl_dvrp = MAX( nxl, nx_dvrp_l ) nxr_dvrp = MIN( nxr, nx_dvrp_r ) nys_dvrp = MAX( nys, ny_dvrp_s ) nyn_dvrp = MIN( nyn, ny_dvrp_n ) IF ( nxl_dvrp == nxl .AND. nxr_dvrp == nxr .AND. & nys_dvrp == nys .AND. nyn_dvrp == nyn ) THEN dvrp_total_overlap = .TRUE. ELSE dvrp_total_overlap = .FALSE. ENDIF ELSE ! !-- This subdomain does not overlap with the clipping area. Define an !-- arbitrary (small) domain within in the clipping area. dvrp_overlap = .FALSE. dvrp_total_overlap = .FALSE. ! nxl_dvrp = nx_dvrp_l ! nxr_dvrp = nxl_dvrp + 4 ! nys_dvrp = ny_dvrp_s ! nyn_dvrp = nys_dvrp + 4 nxl_dvrp = nxl nxr_dvrp = MIN( nxl+4, nxr ) nys_dvrp = nys nyn_dvrp = MIN( nys+4, nyn ) ENDIF ! !-- Set the maximum time the program can be suspended on user request (by !-- dvrp steering). This variable is defined in module DVRP. DVRP_MAX_SUSPEND_TIME = 7200 ! !-- Allocate array holding the names and limits of the steering variables !-- (must have the same number of elements as array mode_dvrp!) ALLOCATE( steering_dvrp(10) ) ! !-- Check, if output parameters are given and/or allowed !-- and set default-values, where necessary IF ( dvrp_username == ' ' ) THEN message_string = 'dvrp_username is undefined' CALL message( 'init_dvrp', 'PA0195', 1, 2, 0, 6, 0 ) ENDIF IF ( dvrp_output /= 'ftp' .AND. dvrp_output /= 'rtsp' .AND. & dvrp_output /= 'local' ) THEN message_string = 'dvrp_output="' // TRIM( dvrp_output ) // & '" not allowed' CALL message( 'init_dvrp', 'PA0196', 1, 2, 0, 6, 0 ) ENDIF IF ( dvrp_directory == 'default' ) THEN dvrp_directory = TRIM( dvrp_username ) // '/' // TRIM( run_identifier ) ENDIF ! !-- A local dvrserver running always outputs on temporary directory DATA_DVR IF ( local_dvrserver_running ) THEN dvrp_directory = 'DATA_DVR' ENDIF IF ( dvrp_output /= 'local' ) THEN IF ( dvrp_file /= 'default' .AND. dvrp_file /= '/dev/null' ) THEN message_string = 'dvrp_file="' // TRIM( dvrp_file ) // '" not allowed' CALL message( 'init_dvrp', 'PA0197', 1, 2, 0, 6, 0 ) ENDIF ENDIF ! !-- Strings are assigned to strings of special type which have a CHAR( 0 ) !-- (C end-of-character symbol) at their end. This is needed when strings are !-- passed to C routines. dvrp_directory_c = dvrp_directory dvrp_file_c = dvrp_file dvrp_host_c = dvrp_host dvrp_password_c = dvrp_password dvrp_username_c = dvrp_username ! !-- Loop over all output modes choosed m = 1 allocated = .FALSE. DO WHILE ( mode_dvrp(m) /= ' ' ) ! !-- Check, if mode is allowed IF ( mode_dvrp(m)(1:10) /= 'isosurface' .AND. & mode_dvrp(m)(1:6) /= 'slicer' .AND. & mode_dvrp(m)(1:9) /= 'particles' .AND. & mode_dvrp(m)(1:9) /= 'pathlines' ) THEN message_string = 'mode_dvrp="' // TRIM( mode_dvrp(m) ) // & '" not allowed' CALL message( 'init_dvrp', 'PA0198', 1, 2, 0, 6, 0 ) CALL local_stop ENDIF ! !-- Determine prefix for dvrp_file WRITE ( prefix_chr, '(I2.2,''_'')' ) m ! !-- Camera position must be computed and written on file when no dvrp-output !-- has been generated so far (in former runs) ! IF ( dvrp_filecount == 0 ) THEN ! !-- Compute center of domain and distance of camera from center center(1) = ( clip_dvrp_l + clip_dvrp_r ) * 0.5_wp * superelevation_x center(2) = ( clip_dvrp_s + clip_dvrp_n ) * 0.5_wp * superelevation_y center(3) = ( zu(nz_do3d) - zu(nzb) ) * 0.5_wp * superelevation distance = 1.5_wp * MAX( & (clip_dvrp_r-clip_dvrp_l) * superelevation_x, & (clip_dvrp_n-clip_dvrp_s) * superelevation_y, & ( zu(nz_do3d) - zu(nzb) ) * superelevation & ) ! !-- Write camera position on file CALL DVRP_INIT( m-1, 0 ) ! !-- Create filename for camera IF ( dvrp_output == 'rtsp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // '/camera.dvr' dvrp_file_c = dvrp_file CALL DVRP_OUTPUT_RTSP( m-1, dvrp_host_c, dvrp_username_c, & dvrp_password_c, dvrp_directory_c, & dvrp_file_c ) ELSEIF ( dvrp_output == 'ftp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // '.camera.dvr' dvrp_file_c = dvrp_file ! CALL DVRP_OUTPUT_FTP( m-1, 0, dvrp_host_c, dvrp_username_c, & ! dvrp_password_c, dvrp_directory_c, & ! dvrp_file_c ) ELSE IF ( dvrp_file(1:9) /= '/dev/null' ) THEN dvrp_file_local = prefix_chr // TRIM( mode_dvrp(m) ) & // '.camera.dvr' dvrp_file_local_c = dvrp_file_local ELSE dvrp_file_local_c = dvrp_file_c ENDIF CALL DVRP_OUTPUT_LOCAL( m-1, 0, dvrp_file_local_c ) ENDIF CALL DVRP_CAMERA( m-1, center, distance ) ! !-- Define bounding box material and create a bounding box tmp_r = 0.5_wp; tmp_g = 0.5_wp; tmp_b = 0.5_wp; tmp_t = 0.0_wp CALL DVRP_MATERIAL_RGB( m-1, 1, tmp_r, tmp_g, tmp_b, tmp_t ) tmp_1 = 0.01_wp; tmp_2 = clip_dvrp_l * superelevation_x tmp_3 = clip_dvrp_s * superelevation_y tmp_4 = 0.0_wp tmp_5 = (clip_dvrp_r+dx) * superelevation_x tmp_6 = (clip_dvrp_n+dy) * superelevation_y tmp_7 = zu(nz_do3d) * superelevation CALL DVRP_BOUNDINGBOX( m-1, 1, tmp_1, tmp_2, tmp_3, tmp_4, tmp_5, & tmp_6, tmp_7 ) CALL DVRP_VISUALIZE( m-1, 0, 0 ) CALL DVRP_EXIT( m-1 ) ! !-- Write topography isosurface on file IF ( TRIM( topography ) /= 'flat' ) THEN CALL DVRP_INIT( m-1, 0 ) ! !-- Create filename for topography IF ( dvrp_output == 'rtsp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) & // '/topography.dvr' dvrp_file_c = dvrp_file CALL DVRP_OUTPUT_RTSP( m-1, dvrp_host_c, dvrp_username_c, & dvrp_password_c, dvrp_directory_c, & dvrp_file_c ) ELSEIF ( dvrp_output == 'ftp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) & // '.topography.dvr' dvrp_file_c = dvrp_file ! CALL DVRP_OUTPUT_FTP( m-1, 0, dvrp_host_c, dvrp_username_c, & ! dvrp_password_c, dvrp_directory_c, & ! dvrp_file_c ) ELSE IF ( dvrp_file(1:9) /= '/dev/null' ) THEN dvrp_file_local = prefix_chr // TRIM( mode_dvrp(m) ) & // '.topography.dvr' dvrp_file_local_c = dvrp_file_local ELSE dvrp_file_local_c = dvrp_file_c ENDIF CALL DVRP_OUTPUT_LOCAL( m-1, 0, dvrp_file_local_c ) ENDIF ! !-- Determine local gridpoint coordinates IF ( .NOT. allocated ) THEN ALLOCATE( xcoor_dvrp(nxl_dvrp:nxr_dvrp+1), & ycoor_dvrp(nys_dvrp:nyn_dvrp+1), & zcoor_dvrp(nzb:nz_do3d) ) allocated = .TRUE. DO i = nxl_dvrp, nxr_dvrp+1 xcoor_dvrp(i) = i * dx * superelevation_x ENDDO DO j = nys_dvrp, nyn_dvrp+1 ycoor_dvrp(j) = j * dy * superelevation_y ENDDO zcoor_dvrp = zu(nzb:nz_do3d) * superelevation nx_dvrp = nxr_dvrp+1 - nxl_dvrp + 1 ny_dvrp = nyn_dvrp+1 - nys_dvrp + 1 nz_dvrp = nz_do3d - nzb + 1 ENDIF ! !-- Define the grid used by dvrp CALL DVRP_NO_GLOBAL_GRID( m-1, 1 ) CALL DVRP_GRID( m-1, nx_dvrp, ny_dvrp, nz_dvrp, xcoor_dvrp, & ycoor_dvrp, zcoor_dvrp ) tmp_r = topography_color(1) tmp_g = topography_color(2) tmp_b = topography_color(3) tmp_t = 0.0_wp CALL DVRP_MATERIAL_RGB( m-1, 1, tmp_r, tmp_g, tmp_b, tmp_t ) ! !-- Compute and plot isosurface in dvr-format ALLOCATE( local_pf(nxl_dvrp:nxr_dvrp+1,nys_dvrp:nyn_dvrp+1, & nzb:nz_do3d) ) local_pf = 0.0_wp IF ( dvrp_overlap ) THEN DO i = nxl_dvrp, nxr_dvrp+1 DO j = nys_dvrp, nyn_dvrp+1 IF ( nzb_s_inner(j,i) > 0 ) THEN local_pf(i,j,nzb:nzb_s_inner(j,i)) = 1.0_wp ENDIF ENDDO ENDDO ENDIF CALL DVRP_DATA( m-1, local_pf, 1, nx_dvrp, ny_dvrp, nz_dvrp, & cyclic_dvrp, cyclic_dvrp, cyclic_dvrp ) tmp_th = 1.0_wp CALL DVRP_THRESHOLD( m-1, tmp_th ) ! !-- Reduce the number of polygones, if required IF ( cluster_size > 1 ) THEN cluster_size_x = cluster_size cluster_size_y = cluster_size cluster_size_z = cluster_size cluster_mode = 4 ! vertex clustering mode gradient_normals = 0 ! use flat-shading CALL DVRP_CLUSTER_SIZE( m-1, cluster_size_x, cluster_size_y, & cluster_size_z ) CALL DVRP_CLUSTERING_MODE( m-1, cluster_mode ) CALL DVRP_GRADIENTNORMALS( m-1, gradient_normals ) ! !-- Set parameter for vertex clustering mode 4. !-- ATTENTION: A seperate procedure for setting cluster_alpha will !-- be in the next version of libDVRP (Feb 09) cluster_alpha = 38.0_wp CALL DVRP_THRESHOLD( -(m-1)-1, cluster_alpha ) CALL DVRP_VISUALIZE( m-1, 21, 0 ) ELSE ! !-- No polygon reduction CALL DVRP_VISUALIZE( m-1, 1, 0 ) ENDIF DEALLOCATE( local_pf ) CALL DVRP_EXIT( m-1 ) ENDIF ! !-- Write the ground plate (z=0) isosurface on file CALL DVRP_INIT( m-1, 0 ) ! !-- Create filename for surface IF ( dvrp_output == 'rtsp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // & '/groundplate.dvr' dvrp_file_c = dvrp_file CALL DVRP_OUTPUT_RTSP( m-1, dvrp_host_c, dvrp_username_c, & dvrp_password_c, dvrp_directory_c, & dvrp_file_c ) ELSEIF ( dvrp_output == 'ftp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // & '.groundplate.dvr' dvrp_file_c = dvrp_file ! CALL DVRP_OUTPUT_FTP( m-1, 0, dvrp_host_c, dvrp_username_c, & ! dvrp_password_c, dvrp_directory_c, & ! dvrp_file_c ) ELSE IF ( dvrp_file(1:9) /= '/dev/null' ) THEN dvrp_file_local = prefix_chr // TRIM( mode_dvrp(m) ) & // '.groundplate.dvr' dvrp_file_local_c = dvrp_file_local ELSE dvrp_file_local_c = dvrp_file_c ENDIF CALL DVRP_OUTPUT_LOCAL( m-1, 0, dvrp_file_local_c ) ENDIF ! !-- Determine local gridpoint coordinates IF ( .NOT. allocated ) THEN ALLOCATE( xcoor_dvrp(nxl_dvrp:nxr_dvrp+1), & ycoor_dvrp(nys_dvrp:nyn_dvrp+1), & zcoor_dvrp(nzb:nz_do3d) ) allocated = .TRUE. DO i = nxl_dvrp, nxr_dvrp+1 xcoor_dvrp(i) = i * dx * superelevation_x ENDDO DO j = nys_dvrp, nyn_dvrp+1 ycoor_dvrp(j) = j * dy * superelevation_y ENDDO zcoor_dvrp = zu(nzb:nz_do3d) * superelevation nx_dvrp = nxr_dvrp+1 - nxl_dvrp + 1 ny_dvrp = nyn_dvrp+1 - nys_dvrp + 1 nz_dvrp = nz_do3d - nzb + 1 ENDIF ! !-- Define the grid used by dvrp CALL DVRP_NO_GLOBAL_GRID( m-1, 1 ) CALL DVRP_GRID( m-1, nx_dvrp, ny_dvrp, nz_dvrp, xcoor_dvrp, & ycoor_dvrp, zcoor_dvrp ) tmp_r = groundplate_color(1) tmp_g = groundplate_color(2) tmp_b = groundplate_color(3) tmp_t = 0.0_wp CALL DVRP_MATERIAL_RGB( m-1, 1, tmp_r, tmp_g, tmp_b, tmp_t ) ! !-- Compute and plot isosurface in dvr-format ALLOCATE( local_pf(nxl_dvrp:nxr_dvrp+1,nys_dvrp:nyn_dvrp+1, & nzb:nz_do3d) ) local_pf = 0.0_wp IF (dvrp_overlap ) local_pf(:,:,0) = 1.0_wp CALL DVRP_DATA( m-1, local_pf, 1, nx_dvrp, ny_dvrp, nz_dvrp, & cyclic_dvrp, cyclic_dvrp, cyclic_dvrp ) tmp_th = 1.0_wp CALL DVRP_THRESHOLD( m-1, tmp_th ) ! !-- Always reduce the number of polygones as much as possible cluster_size_x = 5 cluster_size_y = 5 cluster_size_z = 5 cluster_mode = 4 ! vertex clustering mode gradient_normals = 0 ! use flat-shading CALL DVRP_CLUSTER_SIZE( m-1, cluster_size_x, cluster_size_y, & cluster_size_z ) CALL DVRP_CLUSTERING_MODE( m-1, cluster_mode ) CALL DVRP_GRADIENTNORMALS( m-1, gradient_normals ) ! !-- Set parameter for vertex clustering mode 4. !-- ATTENTION: A seperate procedure for setting cluster_alpha will be in !-- the next version of libDVRP (Feb 09) cluster_alpha = 38.0_wp CALL DVRP_THRESHOLD( -(m-1)-1, cluster_alpha ) CALL DVRP_VISUALIZE( m-1, 21, 0 ) DEALLOCATE( local_pf ) CALL DVRP_EXIT( m-1 ) ! ENDIF ! !-- Initialize dvrp for all dvrp-calls during the run CALL DVRP_INIT( m-1, 0 ) ! !-- Preliminary definition of filename for dvrp-output IF ( dvrp_output == 'rtsp' ) THEN ! !-- First initialize parameters for possible interactive steering. !-- Every parameter has to be passed to the respective stream. pn = 1 ! !-- Initialize threshold counter needed for initialization of the !-- isosurface steering variables tv = 0 DO WHILE ( mode_dvrp(pn) /= ' ' ) IF ( mode_dvrp(pn)(1:10) == 'isosurface' ) THEN READ ( mode_dvrp(pn), '(10X,I2)' ) vn steering_dvrp(pn)%name = do3d(0,vn) tv = tv + 1 IF ( do3d(0,vn)(1:1) == 'w' ) THEN steering_dvrp(pn)%min = -4.0_wp steering_dvrp(pn)%max = 5.0_wp ELSE steering_dvrp(pn)%min = 288.0_wp steering_dvrp(pn)%max = 292.0_wp ENDIF name_c = TRIM( do3d(0,vn) ) tmp_thr = threshold(tv) CALL DVRP_STEERING_INIT( m-1, name_c, steering_dvrp(pn)%min, & steering_dvrp(pn)%max, tmp_thr ) ELSEIF ( mode_dvrp(pn)(1:6) == 'slicer' ) THEN READ ( mode_dvrp(pn), '(6X,I2)' ) vn steering_dvrp(pn)%name = do2d(0,vn) name_c = TRIM( do2d(0,vn) ) l = MAX( 2, LEN_TRIM( do2d(0,vn) ) ) section_chr = do2d(0,vn)(l-1:l) SELECT CASE ( section_chr ) CASE ( 'xy' ) steering_dvrp(pn)%imin = 0 steering_dvrp(pn)%imax = nz_do3d slicer_position_dvrp(pn) = section(1,1) CALL DVRP_STEERING_INIT( m-1, name_c, & steering_dvrp(pn)%imin, & steering_dvrp(pn)%imax, & slicer_position_dvrp(pn) ) CASE ( 'xz' ) steering_dvrp(pn)%imin = 0 steering_dvrp(pn)%imax = ny slicer_position_dvrp(pn) = section(1,2) CALL DVRP_STEERING_INIT( m-1, name_c, & steering_dvrp(pn)%imin, & steering_dvrp(pn)%imax, & slicer_position_dvrp(pn) ) CASE ( 'yz' ) steering_dvrp(pn)%imin = 0 steering_dvrp(pn)%imax = nx slicer_position_dvrp(pn) = section(1,3) CALL DVRP_STEERING_INIT( m-1, name_c, & steering_dvrp(pn)%imin, & steering_dvrp(pn)%imax, & slicer_position_dvrp(pn) ) END SELECT ENDIF pn = pn + 1 ENDDO dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // '/*****.dvr' dvrp_file_c = dvrp_file CALL DVRP_OUTPUT_RTSP( m-1, dvrp_host_c, dvrp_username_c, & dvrp_password_c, dvrp_directory_c, & dvrp_file_c ) ELSEIF ( dvrp_output == 'ftp' ) THEN dvrp_file = prefix_chr // TRIM( mode_dvrp(m) ) // '.%05d.dvr' dvrp_file_c = dvrp_file ! CALL DVRP_OUTPUT_FTP( m-1, 0, dvrp_host_c, dvrp_username_c, & ! dvrp_password_c, dvrp_directory_c, dvrp_file_c ) ELSE IF ( dvrp_file(1:9) /= '/dev/null' ) THEN dvrp_file_local = prefix_chr // TRIM( mode_dvrp(m) ) & // '_%05d.dvr' dvrp_file_local_c = dvrp_file_local ELSE dvrp_file_local_c = dvrp_file_c ENDIF CALL DVRP_OUTPUT_LOCAL( m-1, 0, dvrp_file_local_c ) ENDIF ! !-- Determine local gridpoint coordinates IF ( .NOT. allocated ) THEN ALLOCATE( xcoor_dvrp(nxl_dvrp:nxr_dvrp+1), & ycoor_dvrp(nys_dvrp:nyn_dvrp+1), & zcoor_dvrp(nzb:nz_do3d) ) allocated = .TRUE. DO i = nxl_dvrp, nxr_dvrp+1 xcoor_dvrp(i) = i * dx * superelevation_x ENDDO DO j = nys_dvrp, nyn_dvrp+1 ycoor_dvrp(j) = j * dy * superelevation_y ENDDO zcoor_dvrp = zu(nzb:nz_do3d) * superelevation nx_dvrp = nxr_dvrp+1 - nxl_dvrp + 1 ny_dvrp = nyn_dvrp+1 - nys_dvrp + 1 nz_dvrp = nz_do3d - nzb + 1 ENDIF ! !-- Define the grid used by dvrp IF ( mode_dvrp(m) /= 'pathlines' ) THEN CALL DVRP_NO_GLOBAL_GRID( m-1, 1 ) ENDIF CALL DVRP_GRID( m-1, nx_dvrp, ny_dvrp, nz_dvrp, xcoor_dvrp, ycoor_dvrp, & zcoor_dvrp ) IF ( mode_dvrp(m) == 'pathlines' ) THEN tmp_x1 = 0.0_wp; tmp_y1 = 0.0_wp; tmp_z1 = 0.0_wp tmp_x2 = 1.0_wp; tmp_y2 = 1.0_wp; tmp_z2 = 0.3_wp CALL DVRP_CUBIC_SEEDING( m-1, tmp_x1, tmp_y1, tmp_z1, tmp_x2, tmp_y2,& tmp_z2, pathlines_linecount, 2, 0 ) ! !-- Set wavecount and wavetime CALL DVRP_PATHLINES_BEHAVIOUR_WAVE( m-1, pathlines_wavecount, & pathlines_wavetime, & pathlines_fadeintime, & pathlines_fadeouttime ) ! !-- Set pathline length CALL DVRP_PATHLINES_SETMAXHISTORY( m-1, pathlines_maxhistory ) CALL DVRP_PATHLINES_SETFADING( m-1, 1, 0.0_wp ) CALL DVRP_INIT_PATHLINES( m-1, 0 ) ENDIF IF ( mode_dvrp(m)(1:9) == 'particles' ) THEN ! !-- Define a default colourtable for particles DO i = 1, 11 interval_values_dvrp_prt(1,i) = i - 1.0_wp interval_values_dvrp_prt(2,i) = REAL( i, KIND=wp ) interval_h_dvrp_prt(:,i) = 270.0_wp - ( i - 1.0_wp ) * 9.0_wp ENDDO DO i = 12, 22 interval_values_dvrp_prt(1,i) = i - 1.0_wp interval_values_dvrp_prt(2,i) = REAL( i, KIND=wp ) interval_h_dvrp_prt(:,i) = 70.0_wp - ( i - 12.0_wp ) * 9.5_wp ENDDO dvrp_colortable_entries_prt = 22 ENDIF m = m + 1 ENDDO #endif END SUBROUTINE init_dvrp !------------------------------------------------------------------------------! ! Description: ! ------------ !> Initializes logging events for time measurement with dvrp software !> and splits one PE from the global communicator in case that dvrp output !> shall be done by one single PE. !------------------------------------------------------------------------------! SUBROUTINE init_dvrp_logging #if defined( __dvrp_graphics ) USE dvrp_variables, & ONLY: use_seperate_pe_for_dvrp_output USE kinds USE pegrid IMPLICIT NONE CHARACTER (LEN=4) :: chr !< INTEGER(iwp) :: idummy !< ! !-- Initialize logging of calls by DVRP graphic software CALL DVRP_LOG_INIT( 'DVRP_LOG' // CHAR( 0 ), 0 ) ! !-- User-defined logging events: #1 (total time needed by PALM) CALL DVRP_LOG_SYMBOL( 1, 'PALM_total' // CHAR( 0 ) ) CALL DVRP_LOG_SYMBOL( 2, 'PALM_timestep' // CHAR( 0 ) ) CALL DVRP_LOG_EVENT( 1, 1 ) #if defined( __parallel ) ! !-- Find out, if dvrp output shall be done by a dedicated PE CALL GET_ENVIRONMENT_VARIABLE( 'use_seperate_pe_for_dvrp_output', chr, & idummy ) IF ( chr == 'true' ) THEN use_seperate_pe_for_dvrp_output = .TRUE. ! !-- Adjustment for new MPI-1 coupling. This might be unnecessary. #if defined( __mpi2 ) CALL DVRP_SPLIT( MPI_COMM_WORLD, comm_palm ) #else IF ( coupling_mode /= 'uncoupled' ) THEN message_string = 'split of communicator not realized with' // & ' MPI1 coupling atmosphere-ocean' CALL message( 'init_dvrp_logging', 'PA0199', 1, 2, 0, 6, 0 ) CALL DVRP_SPLIT( comm_inter, comm_palm ) ELSE CALL DVRP_SPLIT( MPI_COMM_WORLD, comm_palm ) ENDIF #endif CALL MPI_COMM_SIZE( comm_palm, numprocs, ierr ) ENDIF #endif #endif END SUBROUTINE init_dvrp_logging !------------------------------------------------------------------------------! ! Description: ! ------------ !> Exit of dvrp software and finish dvrp logging !------------------------------------------------------------------------------! SUBROUTINE close_dvrp #if defined( __dvrp_graphics ) USE DVRP USE dvrp_variables, & ONLY: use_seperate_pe_for_dvrp_output USE kinds INTEGER(iwp) :: m !< ! !-- If required, close dvrp-software and logging of dvrp-calls IF ( dt_dvrp /= 9999999.9_wp ) THEN m = 1 DO WHILE ( mode_dvrp(m) /= ' ' ) CALL DVRP_EXIT( m-1 ) m = m + 1 ENDDO CALL DVRP_LOG_EVENT( -1, 1 ) ! Logging of total cpu-time used by PALM IF ( use_seperate_pe_for_dvrp_output ) THEN #ifndef __nec CALL DVRP_SPLIT_EXIT( 1 ) ! Argument 0: reduced output #endif ELSE CALL DVRP_LOG_EXIT( 1 ) ! Argument 0: reduced output ENDIF ENDIF #endif END SUBROUTINE close_dvrp