!> @agent_preprocessing.f90
!------------------------------------------------------------------------------!
! This file is part of the PALM model system.
!
! 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 1997-2018 Leibniz Universitaet Hannover
!------------------------------------------------------------------------------!
!
! Current revisions:
! ------------------
!
!
! Former revisions:
! -----------------!
! $Id: agent_preprocessing.f90 3216 2018-08-29 10:22:12Z raasch $
! Bubfix for gfortran: reordering of type definitions
!
! 3210 2018-08-28 07:31:13Z sward
! Bugfix: changed intrinsic SIZEOF to STORAGE_SIZE
!
! 3208 2018-08-27 13:10:50Z sward
! Renamed nav_mesh to agent_preprocessing, adapted terminal output
!
! 3198 2018-08-15 09:23:10Z sward
! Reduced tolerance_dp to 3 entries, fixed its initialization
!
! 3168 2018-07-25 06:40:29Z sward
! Updated NetCDF ororgraphy and building input
!
! Initial revision
!
!
! Description:
! ------------
!> Reads topography and building data and converts this information into a
!> navigation mesh (NavMesh, a visibility graph). This mesh is necessary for
!> the use of the Multi Agent System in PALM for the agents to navigate in
!> complex (urban) terrain.
!------------------------------------------------------------------------------!
MODULE kinds
IMPLICIT NONE
!
!-- Floating point kinds
INTEGER, PARAMETER :: sp = 4 !< single precision (32 bit)
INTEGER, PARAMETER :: dp = 8 !< double precision (64 bit)
!
!-- Integer kinds
INTEGER, PARAMETER :: isp = SELECTED_INT_KIND( 9 ) !< single precision (32 bit)
INTEGER, PARAMETER :: idp = SELECTED_INT_KIND( 14 ) !< double precision (64 bit)
!
!-- Set kinds to be used as defaults
INTEGER, PARAMETER :: wp = dp !< default real kind
INTEGER, PARAMETER :: iwp = isp !< default integer kind
SAVE
END MODULE kinds
MODULE variables
USE kinds
CHARACTER(LEN=3) :: char_lod = 'lod' !< name of level-of-detail attribute in NetCDF file
CHARACTER(LEN=10) :: char_fill = '_FillValue' !< name of fill value attribute in NetCDF file
CHARACTER(LEN=128) :: runname !< Run name
LOGICAL :: internal_buildings = .FALSE. !< Flag that indicates whether buildings within closed courtyards should be deleted
LOGICAL :: flag_2d = .FALSE. !< Flag that indicates that 2d buildings will be used in all cases
INTEGER(iwp) :: i !< Index along x
INTEGER(iwp) :: j !< Index along y
INTEGER(iwp) :: nx = 99999 !< Number of grid points in x-direction
INTEGER(iwp) :: ny = 99999 !< Number of grid points in x-direction
INTEGER(iwp) :: nov !< Number of vertices
INTEGER(iwp) :: polygon_counter !< Iterator for the number of building polygons
INTEGER(iwp) :: number_of_connections = 0 !< Counter for number of connections in mesh
INTEGER(iwp) :: i_cn !< Min number of corners left in polygons after Douglas Poiker algorithm
INTEGER(iwp) :: i_sc !< Cycle number for Douglas-Peucker algorithm
INTEGER(iwp) :: nc_stat !< return value of nf90 function call
INTEGER(iwp) :: vertex_counter !< Counter: total number of vertices
INTEGER, DIMENSION(:,:), ALLOCATABLE :: wall_flags_0 !< Bit-array containing surface information
INTEGER, DIMENSION(:,:), ALLOCATABLE :: polygon_id !< Identifies each grid point as part of exactly one building
REAL(wp) :: ddx !< inverse of dx
REAL(wp) :: ddy !< inverse of dy
REAL(wp) :: dx = 99999.9_wp !< grid spacing in x-direction
REAL(wp) :: dy = 99999.9_wp !< grid spacing in x-direction
REAL(wp) :: dz = 99999.9_wp !< grid spacing in x-direction
REAL(wp) :: finish !< variable for CPU time measurement
REAL(wp) :: start !< variable for CPU time measurement
REAL(wp), DIMENSION(0:2) :: tolerance_dp = 999999.0_wp !< tolerance in Douglas-Peucker algorithm
REAL(wp), DIMENSION(:,:), ALLOCATABLE :: obstacle_height !< height of obstacles
!
!-- Define data structure where the dimension and type of the input depends
!-- on the given level of detail.
!-- For buildings, the input is either 2D float, or 3d byte.
TYPE build_in
INTEGER(iwp) :: lod = 1 !< level of detail
INTEGER(KIND=1) :: fill2 = -127 !< fill value for lod = 2
INTEGER(iwp) :: nz !< number of vertical layers in file
INTEGER(KIND=1), DIMENSION(:,:,:), ALLOCATABLE :: var_3d !< 3d variable (lod = 2)
REAL(wp), DIMENSION(:), ALLOCATABLE :: z !< vertical coordinate for 3D building, used for consistency check
LOGICAL :: from_file = .FALSE. !< flag indicating whether an input variable is available and read from file or default values are used
REAL(wp) :: fill1 = -9999.9_wp !< fill values for lod = 1
REAL(wp), DIMENSION(:,:), ALLOCATABLE :: var_2d !< 2d variable (lod = 1)
END TYPE build_in
!
!-- Topography grid point
TYPE grid_point
LOGICAL :: checked !< Flag to indicate whether this grid point has been evaluated already
INTEGER(iwp) :: i !< x-index
INTEGER(iwp) :: j !< y-index
INTEGER(iwp) :: polygon_id !< ID of the polygon this grid point belongs to
END TYPE grid_point
!
!-- Node in the visibility graph navigation mesh
TYPE mesh_point
INTEGER(iwp) :: polygon_id !< Polygon the point belongs to
INTEGER(iwp) :: vertex_id !< Vertex in the polygon
INTEGER(iwp) :: noc !< number of connections
INTEGER(iwp) :: origin_id !< ID of previous mesh point on path (A*)
REAL(wp) :: cost_so_far !< Cost to reach this mesh point (A*)
REAL(wp) :: x !< x-coordinate
REAL(wp) :: y !< y-coordinate
REAL(wp) :: x_s !< corner shifted outward from building by 1m (x)
REAL(wp) :: y_s !< corner shifted outward from building by 1m (y)
INTEGER(iwp), DIMENSION(:), ALLOCATABLE :: connected_vertices !< Index of connected vertices
REAL(wp), DIMENSION(:), ALLOCATABLE :: distance_to_vertex !< Distance to each vertex
END TYPE mesh_point
!
!-- Vertex of a polygon
TYPE vertex_type
LOGICAL :: delete !< Flag to mark vertex for deletion
REAL(wp) :: x !< x-coordinate
REAL(wp) :: y !< y-coordinate
END TYPE vertex_type
!
!-- Polygon containing a number of vertices
TYPE polygon_type
INTEGER(iwp) :: nov !< Number of vertices in this polygon
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: vertices !< Array of vertices
END TYPE polygon_type
!
!-- Define data type to read 2D real variables
TYPE real_2d
LOGICAL :: from_file = .FALSE. !< flag indicating whether an input variable is available and read from file or default values are used
REAL(wp) :: fill = -9999.9_wp !< fill value
REAL(wp), DIMENSION(:,:), ALLOCATABLE :: var !< respective variable
END TYPE real_2d
!
!-- Define data type to read 2D real variables
TYPE real_3d
LOGICAL :: from_file = .FALSE. !< flag indicating whether an input variable is available and read from file or default values are used
INTEGER(iwp) :: nz !< number of grid points along vertical dimension
REAL(wp) :: fill = -9999.9_wp !< fill value
REAL(wp), DIMENSION(:,:,:), ALLOCATABLE :: var !< respective variable
END TYPE real_3d
TYPE(grid_point), DIMENSION(:,:), ALLOCATABLE :: grid !< 2d Topography grid
TYPE(mesh_point), DIMENSION(:), ALLOCATABLE, TARGET :: mesh !< Navigation mesh
TYPE(real_2d) :: terrain_height_f !< input variable for terrain height
TYPE(vertex_type) :: dummy_vertex !< placeholder vertex used for data copying
TYPE(vertex_type) :: null_vertex !< placeholder vertex used for initialisation
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: dummy_v_list !< Dummy for reallocation of polygon array
TYPE(polygon_type), POINTER :: polygon !< Current polygon
TYPE(polygon_type), DIMENSION(:), ALLOCATABLE, TARGET :: polygons !< Building polygons
TYPE(build_in) :: buildings_f !< input variable for buildings
END MODULE variables
MODULE data_input
USE kinds
USE variables
#if defined ( __netcdf )
USE NETCDF
#endif
INTERFACE get_variable
MODULE PROCEDURE get_variable_1d_int
MODULE PROCEDURE get_variable_1d_real
MODULE PROCEDURE get_variable_2d_int8
MODULE PROCEDURE get_variable_2d_int32
MODULE PROCEDURE get_variable_2d_real
MODULE PROCEDURE get_variable_3d_int8
MODULE PROCEDURE get_variable_3d_real
MODULE PROCEDURE get_variable_4d_real
END INTERFACE get_variable
INTERFACE get_attribute
MODULE PROCEDURE get_attribute_real
MODULE PROCEDURE get_attribute_int8
MODULE PROCEDURE get_attribute_int32
MODULE PROCEDURE get_attribute_string
END INTERFACE get_attribute
CONTAINS
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads orography and building information.
!------------------------------------------------------------------------------!
SUBROUTINE netcdf_data_input_topo ( input_trunk )
IMPLICIT NONE
CHARACTER(LEN=*) :: input_trunk !< run path
CHARACTER(LEN=200) :: input_filename !< filename
CHARACTER(LEN=100), DIMENSION(:), ALLOCATABLE :: var_names !< variable names in static input file
INTEGER(iwp) :: i !< running index along x-direction
INTEGER(iwp) :: ii !< running index for IO blocks
INTEGER(iwp) :: k_head !< minimum k index for agents to walk underneath overhanging buildings
INTEGER(iwp) :: id_topo !< NetCDF id of topograhy input file
INTEGER(iwp) :: j !< running index along y-direction
INTEGER(iwp) :: k !< running index along z-direction
INTEGER(iwp) :: num_vars !< number of variables in netcdf input file
INTEGER(iwp) :: skip_n_rows !< counting variable to skip rows while reading topography file
LOGICAL :: netcdf_flag = .FALSE. !< indicates whether netcdf file is used for input
LOGICAL :: lod_flag = .FALSE. !< true if 3d building data is used
LOGICAL :: topo_file_flag = .FALSE. !< true if 3d building data is used
REAL(wp) :: dum !< dummy variable to skip columns while reading topography file
WRITE(*,'((X,A,/))') 'Looking for topography/building information'
INQUIRE( FILE = TRIM( input_trunk )//'_static', EXIST = netcdf_flag )
IF ( netcdf_flag ) THEN
input_filename = TRIM( input_trunk )//'_static'
WRITE(*,'(2(3X,A,/))') 'Topography/building data will be used from', &
TRIM( input_trunk )//'_static'
ELSE
WRITE(*,'(2(3X,A,/))') 'No static driver was found.', &
'Trying to read building data from _topo file.'
input_filename = TRIM( input_trunk )//'_topo'
INQUIRE( FILE = TRIM( input_filename ), EXIST = topo_file_flag )
IF ( .NOT. topo_file_flag ) THEN
WRITE(*,'(6(3X,A,/))') &
'No ASCII topography file was found in INPUT directory.', &
'Make sure you provided building data in the form of either', &
' (A) a static driver (_static) or', &
' (B) an ASCII topography file (_topo).', &
NEW_LINE('A')//'Aborting nav_mesh program...'
STOP
ENDIF
WRITE(*,'(2(3X,A,/))') 'Topography/building data will be used from', &
TRIM( input_trunk )//'_topo'
ENDIF
!
!-- Input via palm-input data standard
IF ( netcdf_flag ) THEN
#if defined ( __netcdf )
!
!-- Open file in read-only mode
CALL open_read_file( TRIM(input_filename) , id_topo )
!
!-- At first, inquire all variable names.
!-- This will be used to check whether an input variable exist or not.
nc_stat = NF90_INQUIRE( id_topo, NVARIABLES = num_vars )
CALL handle_error( 'inquire_num_variables', 534 )
!
!-- Allocate memory to store variable names and inquire them.
ALLOCATE( var_names(1:num_vars) )
CALL inquire_variable_names( id_topo, var_names )
!
!-- Terrain height. First, get variable-related _FillValue attribute
IF ( check_existence( var_names, 'zt' ) ) THEN
terrain_height_f%from_file = .TRUE.
CALL get_attribute( id_topo, char_fill, &
terrain_height_f%fill, &
.FALSE., 'zt' )
!
!-- PE-wise reading of 2D terrain height.
ALLOCATE ( terrain_height_f%var(0:ny,0:nx) )
DO i = 0, nx
CALL get_variable( id_topo, 'zt', &
i, terrain_height_f%var(:,i) )
ENDDO
ELSE
terrain_height_f%from_file = .FALSE.
ENDIF
!
!-- Read building height. First, read its _FillValue attribute,
!-- as well as lod attribute
buildings_f%from_file = .FALSE.
IF ( check_existence( var_names, 'buildings_2d' ) ) THEN
buildings_f%from_file = .TRUE.
CALL get_attribute( id_topo, char_lod, buildings_f%lod, &
.FALSE., 'buildings_2d' )
CALL get_attribute( id_topo, char_fill, &
buildings_f%fill1, &
.FALSE., 'buildings_2d' )
!
!-- Read 2D topography
IF ( buildings_f%lod == 1 ) THEN
ALLOCATE ( buildings_f%var_2d(0:ny,0:nx) )
DO i = 0, nx
CALL get_variable( id_topo, 'buildings_2d', &
i, buildings_f%var_2d(:,i) )
ENDDO
ELSE
WRITE(*,'(A)') 'NetCDF attribute lod ' // &
'(level of detail) is not set properly.'
ENDIF
ENDIF
!
!-- If available, also read 3D building information. If both are
!-- available, use 3D information. Do this only if the flag that indicates
!-- that 2d buildings shall be used no matter what is false.
IF ( check_existence( var_names, 'buildings_3d' ) &
.AND. .NOT. flag_2d ) &
THEN
lod_flag = .TRUE.
buildings_f%from_file = .TRUE.
CALL get_attribute( id_topo, char_lod, buildings_f%lod, &
.FALSE., 'buildings_3d' )
CALL get_attribute( id_topo, char_fill, &
buildings_f%fill2, &
.FALSE., 'buildings_3d' )
CALL get_dimension_length( id_topo, buildings_f%nz, 'z' )
IF ( buildings_f%lod == 2 ) THEN
ALLOCATE( buildings_f%z(0:buildings_f%nz-1) )
CALL get_variable( id_topo, 'z', buildings_f%z )
ALLOCATE( buildings_f%var_3d(0:buildings_f%nz-1, &
0:ny,0:nx) )
buildings_f%var_3d = 0
!
!-- Read data PE-wise. Read yz-slices.
DO i = 0, nx
DO j = 0, ny
CALL get_variable( id_topo, 'buildings_3d', &
i, j, &
buildings_f%var_3d(:,j,i) )
ENDDO
ENDDO
ELSE
WRITE(*,'(A)') 'NetCDF attribute lod ' // &
'(level of detail) is not set properly.'
ENDIF
ENDIF
!
!-- Close topography input file
CALL close_input_file( id_topo )
#endif
!
!-- ASCII input
ELSE
OPEN( 90, FILE= input_filename, &
STATUS='OLD', FORM='FORMATTED' )
!
!-- Read data from nyn to nys and nxl to nxr. Therefore, skip
!-- column until nxl-1 is reached
ALLOCATE ( buildings_f%var_2d(0:ny,0:nx) )
DO j = ny, 0, -1
READ( 90, *, ERR=11, END=11 ) &
( buildings_f%var_2d(j,i), i = 0, nx )
ENDDO
GOTO 12
11 WRITE(*,'(2A)') 'errors in file ',input_filename
12 CLOSE( 90 )
buildings_f%from_file = .TRUE.
ENDIF
!
!-- In case no terrain height is provided by static input file, allocate
!-- array nevertheless and set terrain height to 0, which simplifies
!-- topography initialization.
IF ( .NOT. terrain_height_f%from_file ) THEN
ALLOCATE ( terrain_height_f%var(0:ny,0:nx) )
terrain_height_f%var = 0.0_wp
ENDIF
!
!-- Transfer read data to uniform format: For agents the only relevant
!-- information is whether they can walk or not at ground level.
k_head = CEILING(2./dz)
IF ( buildings_f%from_file ) THEN
IF ( lod_flag ) THEN
obstacle_height(0:nx,0:ny) = 1.
DO j = 0, ny
DO i = 0, nx
!
!-- For this purpose, an overhanging structure that an angent
!-- can walk beneath (e.g. a doorway) is not considered an
!-- obstacle.
IF ( ALL( buildings_f%var_3d(0:k_head,j,i) == 0 ) ) THEN
obstacle_height(i,j) = 0.
ENDIF
ENDDO
ENDDO
ELSE
DO j = 0, ny
DO i = 0, nx
obstacle_height(i,j) = buildings_f%var_2d(j,i)
ENDDO
ENDDO
ENDIF
ELSE
WRITE(*,*) 'No building data was read from file. There will be no' //&
'navigation data available to agents.'
ENDIF
END SUBROUTINE netcdf_data_input_topo
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Checks if a given variables is on file
!------------------------------------------------------------------------------!
FUNCTION check_existence( vars_in_file, var_name )
IMPLICIT NONE
CHARACTER(LEN=*) :: var_name !< variable to be checked
CHARACTER(LEN=*), DIMENSION(:) :: vars_in_file !< list of variables in file
INTEGER(iwp) :: i !< loop variable
LOGICAL :: check_existence !< flag indicating whether a variable exist or not - actual return value
i = 1
check_existence = .FALSE.
DO WHILE ( i <= SIZE( vars_in_file ) )
check_existence = TRIM( vars_in_file(i) ) == TRIM( var_name ) .OR. &
check_existence
i = i + 1
ENDDO
RETURN
END FUNCTION check_existence
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Closes an existing netCDF file.
!------------------------------------------------------------------------------!
SUBROUTINE close_input_file( id )
#if defined( __netcdf )
IMPLICIT NONE
INTEGER(iwp), INTENT(INOUT) :: id !< file id
nc_stat = NF90_CLOSE( id )
CALL handle_error( 'close', 537 )
#endif
END SUBROUTINE close_input_file
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Opens an existing netCDF file for reading only and returns its id.
!------------------------------------------------------------------------------!
SUBROUTINE open_read_file( filename, id )
#if defined( __netcdf )
IMPLICIT NONE
CHARACTER (LEN=*), INTENT(IN) :: filename !< filename
INTEGER(iwp), INTENT(INOUT) :: id !< file id
LOGICAL :: file_open = .FALSE.
nc_stat = NF90_OPEN( filename, NF90_NOWRITE, id )
CALL handle_error( 'open_read_file', 536 )
#endif
END SUBROUTINE open_read_file
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Get dimension array for a given dimension
!------------------------------------------------------------------------------!
SUBROUTINE get_dimension_length( id, dim_len, variable_name )
#if defined( __netcdf )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< dimension name
CHARACTER(LEN=100) :: dum !< dummy variable to receive return character
INTEGER(iwp) :: dim_len !< dimension size
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_dim !< dimension id
!
!-- First, inquire dimension ID
nc_stat = NF90_INQ_DIMID( id, TRIM( variable_name ), id_dim )
CALL handle_error( 'get_dimension_length', 526 )
!
!-- Inquire dimension length
nc_stat = NF90_INQUIRE_DIMENSION( id, id_dim, dum, LEN = dim_len )
CALL handle_error( 'get_dimension_length', 526 )
#endif
END SUBROUTINE get_dimension_length
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 1D integer variable from file.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_1d_int( id, variable_name, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< dimension id
INTEGER(iwp), DIMENSION(:), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- First, inquire variable ID
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_variable_1d_int', 527 )
!
!-- Inquire dimension length
nc_stat = NF90_GET_VAR( id, id_var, var )
CALL handle_error( 'get_variable_1d_int', 527 )
#endif
END SUBROUTINE get_variable_1d_int
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 1D float variable from file.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_1d_real( id, variable_name, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< dimension id
REAL(wp), DIMENSION(:), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- First, inquire variable ID
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_variable_1d_real', 527 )
!
!-- Inquire dimension length
nc_stat = NF90_GET_VAR( id, id_var, var )
CALL handle_error( 'get_variable_1d_real', 527 )
#endif
END SUBROUTINE get_variable_1d_real
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 2D REAL variable from a file. Reading is done processor-wise,
!> i.e. each core reads its own domain in slices along x.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_2d_real( id, variable_name, i, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
REAL(wp), DIMENSION(0:ny), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var(0:ny), &
start = (/ i+1, 1 /), &
count = (/ 1, ny + 1 /) )
CALL handle_error( 'get_variable_2d_real', 528 )
#endif
END SUBROUTINE get_variable_2d_real
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 2D 32-bit INTEGER variable from file. Reading is done processor-wise,
!> i.e. each core reads its own domain in slices along x.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_2d_int32( id, variable_name, i, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(iwp), DIMENSION(0:ny), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var(0:ny), &
start = (/ i+1, 1 /), &
count = (/ 1, ny + 1 /) )
CALL handle_error( 'get_variable_2d_int32', 529 )
#endif
END SUBROUTINE get_variable_2d_int32
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 2D 8-bit INTEGER variable from file. Reading is done processor-wise,
!> i.e. each core reads its own domain in slices along x.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_2d_int8( id, variable_name, i, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(KIND=1), DIMENSION(0:ny), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var(0:ny), &
start = (/ i+1, 1 /), &
count = (/ 1, ny + 1 /) )
CALL handle_error( 'get_variable_2d_int8', 530 )
#endif
END SUBROUTINE get_variable_2d_int8
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 3D 8-bit INTEGER variable from file.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_3d_int8( id, variable_name, i, j, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(iwp), INTENT(IN) :: j !< index along y direction
INTEGER(iwp) :: n_file !< number of data-points along 3rd dimension
INTEGER(iwp), DIMENSION(1:3) :: id_dim
INTEGER( KIND = 1 ), DIMENSION(0:buildings_f%nz-1), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get length of first dimension, required for the count parameter.
!-- Therefore, first inquired dimension ids
nc_stat = NF90_INQUIRE_VARIABLE( id, id_var, DIMIDS = id_dim )
nc_stat = NF90_INQUIRE_DIMENSION( id, id_dim(3), LEN = n_file )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var, &
start = (/ i+1, j+1, 1 /), &
count = (/ 1, 1, n_file /) )
CALL handle_error( 'get_variable_3d_int8', 531 )
#endif
END SUBROUTINE get_variable_3d_int8
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 3D float variable from file.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_3d_real( id, variable_name, i, j, var )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(iwp), INTENT(IN) :: j !< index along y direction
INTEGER(iwp) :: n3 !< number of data-points along 3rd dimension
INTEGER(iwp), DIMENSION(3) :: id_dim
REAL(wp), DIMENSION(:), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get length of first dimension, required for the count parameter.
!-- Therefore, first inquired dimension ids
nc_stat = NF90_INQUIRE_VARIABLE( id, id_var, DIMIDS = id_dim )
nc_stat = NF90_INQUIRE_DIMENSION( id, id_dim(3), LEN = n3 )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var, &
start = (/ i+1, j+1, 1 /), &
count = (/ 1, 1, n3 /) )
CALL handle_error( 'get_variable_3d_real', 532 )
#endif
END SUBROUTINE get_variable_3d_real
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads a 4D float variable from file. Note, in constrast to 3D versions,
!> dimensions are already inquired and passed so that they are known here.
!------------------------------------------------------------------------------!
SUBROUTINE get_variable_4d_real( id, variable_name, i, j, var, n3, n4 )
IMPLICIT NONE
CHARACTER(LEN=*) :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: i !< index along x direction
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(iwp), INTENT(IN) :: j !< index along y direction
INTEGER(iwp), INTENT(IN) :: n3 !< number of data-points along 3rd dimension
INTEGER(iwp), INTENT(IN) :: n4 !< number of data-points along 4th dimension
INTEGER(iwp), DIMENSION(3) :: id_dim
REAL(wp), DIMENSION(:,:), INTENT(INOUT) :: var !< variable to be read
#if defined( __netcdf )
!
!-- Inquire variable id
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
!
!-- Get variable
nc_stat = NF90_GET_VAR( id, id_var, var, &
start = (/ i+1, j+1, 1, 1 /), &
count = (/ 1, 1, n3, n4 /) )
CALL handle_error( 'get_variable_4d_real', 533 )
#endif
END SUBROUTINE get_variable_4d_real
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Prints out a text message corresponding to the current status.
!------------------------------------------------------------------------------!
SUBROUTINE handle_error( routine_name, errno )
IMPLICIT NONE
CHARACTER(LEN=6) :: message_identifier
CHARACTER(LEN=*) :: routine_name
CHARACTER(LEN=100) :: message_string
INTEGER(iwp) :: errno
#if defined( __netcdf )
IF ( nc_stat /= NF90_NOERR ) THEN
WRITE( message_identifier, '(''NC'',I4.4)' ) errno
message_string = TRIM( NF90_STRERROR( nc_stat ) )
WRITE(*,*) routine_name,' ', message_identifier,' ', TRIM(message_string)
WRITE(*,*) 'Aborting NavMesh-tool'
ENDIF
#endif
END SUBROUTINE handle_error
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Inquires the variable names belonging to a file.
!------------------------------------------------------------------------------!
SUBROUTINE inquire_variable_names( id, var_names )
IMPLICIT NONE
CHARACTER(LEN=*), DIMENSION(:), INTENT(INOUT) :: var_names !< return variable - variable names
INTEGER(iwp) :: i !< loop variable
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: num_vars !< number of variables (unused return parameter)
INTEGER(iwp), DIMENSION(:), ALLOCATABLE :: varids !< dummy array to strore variable ids temporarily
#if defined( __netcdf )
ALLOCATE( varids(1:SIZE(var_names)) )
nc_stat = NF90_INQ_VARIDS( id, NVARS = num_vars, VARIDS = varids )
CALL handle_error( 'inquire_variable_names', 535 )
DO i = 1, SIZE(var_names)
nc_stat = NF90_INQUIRE_VARIABLE( id, varids(i), NAME = var_names(i) )
CALL handle_error( 'inquire_variable_names', 535 )
ENDDO
DEALLOCATE( varids )
#endif
END SUBROUTINE inquire_variable_names
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads global or variable-related attributes of type INTEGER (32-bit)
!------------------------------------------------------------------------------!
SUBROUTINE get_attribute_int32( id, attribute_name, value, global, &
variable_name )
IMPLICIT NONE
CHARACTER(LEN=*) :: attribute_name !< attribute name
CHARACTER(LEN=*), OPTIONAL :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(iwp), INTENT(INOUT) :: value !< read value
LOGICAL, INTENT(IN) :: global !< flag indicating global attribute
#if defined( __netcdf )
!
!-- Read global attribute
IF ( global ) THEN
nc_stat = NF90_GET_ATT( id, NF90_GLOBAL, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_int32 global', 522 )
!
!-- Read attributes referring to a single variable. Therefore, first inquire
!-- variable id
ELSE
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_attribute_int32', 522 )
nc_stat = NF90_GET_ATT( id, id_var, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_int32', 522 )
ENDIF
#endif
END SUBROUTINE get_attribute_int32
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads global or variable-related attributes of type INTEGER (8-bit)
!------------------------------------------------------------------------------!
SUBROUTINE get_attribute_int8( id, attribute_name, value, global, &
variable_name )
IMPLICIT NONE
CHARACTER(LEN=*) :: attribute_name !< attribute name
CHARACTER(LEN=*), OPTIONAL :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
INTEGER(KIND=1), INTENT(INOUT) :: value !< read value
LOGICAL, INTENT(IN) :: global !< flag indicating global attribute
#if defined( __netcdf )
!
!-- Read global attribute
IF ( global ) THEN
nc_stat = NF90_GET_ATT( id, NF90_GLOBAL, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_int8 global', 523 )
!
!-- Read attributes referring to a single variable. Therefore, first inquire
!-- variable id
ELSE
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_attribute_int8', 523 )
nc_stat = NF90_GET_ATT( id, id_var, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_int8', 523 )
ENDIF
#endif
END SUBROUTINE get_attribute_int8
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads global or variable-related attributes of type REAL
!------------------------------------------------------------------------------!
SUBROUTINE get_attribute_real( id, attribute_name, value, global, &
variable_name )
IMPLICIT NONE
CHARACTER(LEN=*) :: attribute_name !< attribute name
CHARACTER(LEN=*), OPTIONAL :: variable_name !< variable name
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
LOGICAL, INTENT(IN) :: global !< flag indicating global attribute
REAL(wp), INTENT(INOUT) :: value !< read value
#if defined( __netcdf )
!
!-- Read global attribute
IF ( global ) THEN
nc_stat = NF90_GET_ATT( id, NF90_GLOBAL, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_real global', 524 )
!
!-- Read attributes referring to a single variable. Therefore, first inquire
!-- variable id
ELSE
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_attribute_real', 524 )
nc_stat = NF90_GET_ATT( id, id_var, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_real', 524 )
ENDIF
#endif
END SUBROUTINE get_attribute_real
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reads global or variable-related attributes of type CHARACTER
!> Remark: reading attributes of type NF_STRING return an error code 56 -
!> Attempt to convert between text & numbers.
!------------------------------------------------------------------------------!
SUBROUTINE get_attribute_string( id, attribute_name, value, global, &
variable_name )
IMPLICIT NONE
CHARACTER(LEN=*) :: attribute_name !< attribute name
CHARACTER(LEN=*), OPTIONAL :: variable_name !< variable name
CHARACTER(LEN=*), INTENT(INOUT) :: value !< read value
INTEGER(iwp), INTENT(IN) :: id !< file id
INTEGER(iwp) :: id_var !< variable id
LOGICAL, INTENT(IN) :: global !< flag indicating global attribute
#if defined( __netcdf )
!
!-- Read global attribute
IF ( global ) THEN
nc_stat = NF90_GET_ATT( id, NF90_GLOBAL, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_string global', 525 )
!
!-- Read attributes referring to a single variable. Therefore, first inquire
!-- variable id
ELSE
nc_stat = NF90_INQ_VARID( id, TRIM( variable_name ), id_var )
CALL handle_error( 'get_attribute_string', 525 )
nc_stat = NF90_GET_ATT( id, id_var, TRIM( attribute_name ), value )
CALL handle_error( 'get_attribute_string',525 )
ENDIF
#endif
END SUBROUTINE get_attribute_string
END MODULE
MODULE mod_functions
USE kinds
PRIVATE
PUBLIC dist_point_to_edge, intersect, is_left, is_right
CONTAINS
!
!-- Calculates distance of point P to edge (A,B). If A = B, calculates
!-- point-to-point distance from A/B to P
FUNCTION dist_point_to_edge ( a_x, a_y, b_x, b_y, p_x, p_y )
IMPLICIT NONE
REAL(wp) :: ab_x !< x-coordinate of vector from A to B
REAL(wp) :: ab_y !< y-coordinate of vector from A to B
REAL(wp) :: ab_d !< inverse length of vector from A to B
REAL(wp) :: ab_u_x !< x-coordinate of vector with direction of ab and length 1
REAL(wp) :: ab_u_y !< y-coordinate of vector with direction of ab and length 1
REAL(wp) :: ba_x !< x-coordinate of vector from B to A
REAL(wp) :: ba_y !< y-coordinate of vector from B to A
REAL(wp) :: ap_x !< x-coordinate of vector from A to P
REAL(wp) :: ap_y !< y-coordinate of vector from A to P
REAL(wp) :: bp_x !< x-coordinate of vector from B to P
REAL(wp) :: bp_y !< y-coordinate of vector from B to P
REAL(wp) :: a_x !< x-coordinate of point A of edge
REAL(wp) :: a_y !< y-coordinate of point A of edge
REAL(wp) :: b_x !< x-coordinate of point B of edge
REAL(wp) :: b_y !< y-coordinate of point B of edge
REAL(wp) :: p_x !< x-coordinate of point P
REAL(wp) :: p_y !< y-coordinate of point P
REAL(wp) :: dist_x !< x-coordinate of point P
REAL(wp) :: dist_y !< y-coordinate of point P
REAL(wp) :: dist_point_to_edge !< y-coordinate of point P
ab_x = - a_x + b_x
ab_y = - a_y + b_y
ba_x = - b_x + a_x
ba_y = - b_y + a_y
ap_x = - a_x + p_x
ap_y = - a_y + p_y
bp_x = - b_x + p_x
bp_y = - b_y + p_y
IF ( ab_x * ap_x + ab_y * ap_y <= 0. ) THEN
dist_point_to_edge = SQRT((a_x - p_x)**2 + (a_y - p_y)**2)
ELSEIF ( ba_x * bp_x + ba_y * bp_y <= 0. ) THEN
dist_point_to_edge = SQRT((b_x - p_x)**2 + (b_y - p_y)**2)
ELSE
ab_d = 1./SQRT((ab_x)**2+(ab_y)**2)
ab_u_x = ab_x*ab_d
ab_u_y = ab_y*ab_d
dist_x = ap_x - (ap_x*ab_u_x+ap_y*ab_u_y)*ab_u_x
dist_y = ap_y - (ap_x*ab_u_x+ap_y*ab_u_y)*ab_u_y
dist_point_to_edge = SQRT( dist_x**2 + dist_y**2 )
ENDIF
RETURN
END FUNCTION dist_point_to_edge
!
!-- Returns true if the line segments AB and PQ share an intersection
FUNCTION intersect ( ax, ay, bx, by, px, py, qx, qy )
IMPLICIT NONE
LOGICAL :: intersect !< return value; TRUE if intersection was found
LOGICAL :: la !< T if a is left of PQ
LOGICAL :: lb !< T if b is left of PQ
LOGICAL :: lp !< T if p is left of AB
LOGICAL :: lq !< T if q is left of AB
LOGICAL :: poss !< flag that indicates if an intersection is still possible
LOGICAL :: ra !< T if a is right of PQ
LOGICAL :: rb !< T if b is right of PQ
LOGICAL :: rp !< T if p is right of AB
LOGICAL :: rq !< T if q is right of AB
REAL(wp) :: ax !< x-coordinate of point A
REAL(wp) :: ay !< y-coordinate of point A
REAL(wp) :: bx !< x-coordinate of point B
REAL(wp) :: by !< y-coordinate of point B
REAL(wp) :: px !< x-coordinate of point P
REAL(wp) :: py !< y-coordinate of point P
REAL(wp) :: qx !< x-coordinate of point Q
REAL(wp) :: qy !< y-coordinate of point Q
intersect = .FALSE.
poss = .FALSE.
!
!-- Intersection is possible only if P and Q are on opposing sides of AB
lp = is_left(ax,ay,bx,by,px,py)
rq = is_right(ax,ay,bx,by,qx,qy)
IF ( lp .AND. rq ) poss = .TRUE.
IF ( .NOT. poss ) THEN
lq = is_left(ax,ay,bx,by,qx,qy)
rp = is_right(ax,ay,bx,by,px,py)
IF ( lq .AND. rp ) poss = .TRUE.
ENDIF
!
!-- Intersection occurs only if above test (poss) was true AND
!-- A and B are on opposing sides of PQ
IF ( poss ) THEN
la = is_left(px,py,qx,qy,ax,ay)
rb = is_right(px,py,qx,qy,bx,by)
IF ( la .AND. rb ) intersect = .TRUE.
IF ( .NOT. intersect ) THEN
lb = is_left(px,py,qx,qy,bx,by)
ra = is_right(px,py,qx,qy,ax,ay)
IF ( lb .AND. ra ) intersect = .TRUE.
ENDIF
ENDIF
RETURN
END FUNCTION intersect
!
!-- Calculates if point P is left of the infinite
!-- line that contains A and B (direction: A to B)
!-- Concept: 2D rotation of two vectors
FUNCTION is_left ( ax, ay, bx, by, px, py )
IMPLICIT NONE
LOGICAL :: is_left !< return value; TRUE if P is left of AB
REAL(wp) :: ax !< x-coordinate of point A
REAL(wp) :: ay !< y-coordinate of point A
REAL(wp) :: bx !< x-coordinate of point B
REAL(wp) :: by !< y-coordinate of point B
REAL(wp) :: px !< x-coordinate of point P
REAL(wp) :: py !< y-coordinate of point P
!
!-- 2D-rotation
is_left = (bx-ax)*(py-ay)-(px-ax)*(by-ay) > 0
!
!-- False if the point is on the line (or very close)
IF ( (ABS(ax-px) < .001 .AND. ABS(ay-py) < .001) .OR. &
(ABS(bx-px) < .001 .AND. ABS(by-py) < .001) ) &
THEN
is_left = .FALSE.
ENDIF
RETURN
END FUNCTION is_left
!
!-- Calculates if point P is right of the infinite
!-- line that contains A and B (direction: A to B)
!-- Concept: 2D rotation of two vectors
FUNCTION is_right ( ax, ay, bx, by, px, py )
IMPLICIT NONE
LOGICAL :: is_right !< return value; TRUE if P is right of AB
REAL(wp), INTENT(IN) :: ax !< x-coordinate of point A
REAL(wp), INTENT(IN) :: ay !< y-coordinate of point A
REAL(wp), INTENT(IN) :: bx !< x-coordinate of point B
REAL(wp), INTENT(IN) :: by !< y-coordinate of point B
REAL(wp), INTENT(IN) :: px !< x-coordinate of point P
REAL(wp), INTENT(IN) :: py !< y-coordinate of point P
!
!-- 2D-rotation
is_right = (bx-ax)*(py-ay)-(px-ax)*(by-ay) < 0
!
!-- False if the point is on the line (or very close)
IF ( (ABS(ax-px) < .001 .AND. ABS(ay-py) < .001) .OR. &
(ABS(bx-px) < .001 .AND. ABS(by-py) < .001) ) &
THEN
is_right = .FALSE.
ENDIF
RETURN
END FUNCTION is_right
END MODULE mod_functions
MODULE polygon_creation
USE kinds
USE mod_functions
USE variables
USE data_input
CONTAINS
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Initialisation, allocation, and reading of some input
!------------------------------------------------------------------------------!
SUBROUTINE init
IMPLICIT NONE
CHARACTER(LEN=20) :: FMT
CHARACTER(LEN=200) :: dirname
CHARACTER(LEN=200) :: rundir
CHARACTER(LEN=200) :: input_trunk
CHARACTER (LEN=80) :: line !<
CHARACTER(LEN=2),DIMENSION(1:5) :: run_pars
INTEGER(iwp) :: status
INTEGER(iwp) :: getcwd
INTEGER(iwp) :: ie
INTEGER(iwp) :: is
LOGICAL :: p3d_flag = .FALSE. !< indicates whether p3d file was found
NAMELIST /prepro_par/ flag_2d, internal_buildings, tolerance_dp
WRITE(*,'(X,A)') &
"o----------------------------------------------o", &
"| o------------------------------------------o |", &
"| | __ ____ ____ ____ | |", &
"| | / _\ ( _ \(_ _) ___ ( _ \ | |", &
"| | / \ ) __/ )( (___) ) __/ | |", &
"| | \_/\_/(__) (__) (__) | |", &
"| | | |", &
"| | Agent Preprocessing Tool for PALM | |", &
"| o------------------------------------------o |", &
"o----------------------------------------------o"
!
!-- Identify run name and Input files
status = getcwd( dirname )
IF ( status /= 0 ) STOP 'getcwd: error'
ie = INDEX(dirname, '/', BACK=.TRUE.)
is = INDEX(dirname(1:ie-1), '/', BACK=.TRUE.)
IF ( TRIM(ADJUSTL(dirname(ie+1:))) /= 'INPUT' ) THEN
WRITE(*,'(3X,A)') 'NavMesh was called from', &
' ', TRIM(ADJUSTL(dirname)), ' ', &
'and is now aborting. Please call this tool', &
'from the INPUT-folder of your job directory.'
STOP
ENDIF
runname = TRIM(ADJUSTL(dirname(is+1:ie-1)))
rundir = TRIM(ADJUSTL(dirname(1:ie)))
input_trunk = TRIM(rundir)//'INPUT/'//TRIM(runname)
!
!-- Check for parameter file
INQUIRE( FILE = TRIM( input_trunk )//'_p3d', EXIST = p3d_flag )
IF ( .NOT. p3d_flag ) THEN
WRITE(*,'(3(3X,A,/))') 'No _p3d file was found. Aborting.', &
'I was looking for the file', &
TRIM( input_trunk )//'_p3d'
STOP
ELSE
WRITE(*,'(2(3X,A,/))') 'The following input file will be used:', &
TRIM( input_trunk )//'_p3d'
ENDIF
!
!-- Read run parameters from run parameter file (_p3d), though not from
!-- namelist.
run_pars = (/'dx','dy','dz','nx','ny'/)
OPEN ( 11, FILE=TRIM(input_trunk)//'_p3d', FORM='FORMATTED', &
STATUS='OLD' )
DO i = 1, SIZE(run_pars)
REWIND ( 11 )
line = ' '
DO WHILE ( INDEX( line, run_pars(i) ) == 0 )
READ ( 11, '(A)', END=10 ) line
IF ( INDEX(line, '!') /= 0 ) THEN
IF ( INDEX(line, run_pars(i)) > INDEX(line, '!' ) ) THEN
line = ' '
CYCLE
ENDIF
ENDIF
ENDDO
line = TRIM(ADJUSTL(line(INDEX(line,'=')+1:INDEX(line,',')-1)))
SELECT CASE (i)
CASE(1)
READ(line,*) dx
CASE(2)
READ(line,*) dy
CASE(3)
READ(line,*) dz
CASE(4)
READ(line,*) nx
CASE(5)
READ(line,*) ny
CASE DEFAULT
END SELECT
ENDDO
10 CONTINUE
!
!-- Try to find prepro package
REWIND ( 11 )
line = ' '
DO WHILE ( INDEX( line, '&prepro_par' ) == 0 )
READ ( 11, '(A)', END=20 ) line
ENDDO
BACKSPACE ( 11 )
!
!-- Read user-defined namelist
READ ( 11, prepro_par )
20 CONTINUE
CLOSE( 11 )
!
!-- If tolerance_dp was not set, put in default values
DO i = 0, 2
IF ( tolerance_dp(i) == 999999.0_wp ) THEN
tolerance_dp(i) = SQRT(dx*dy)*1.41/(2**i)
ELSE
tolerance_dp(i) = tolerance_dp(i)*SQRT(dx*dy)
ENDIF
ENDDO
!
!-- Allocate arrays
ALLOCATE(obstacle_height(-3:nx+3,-3:ny+3), polygon_id(-3:nx+3,-3:ny+3), &
wall_flags_0(-3:nx+3,-3:ny+3), grid(-3:nx+3,-3:ny+3))
!
!-- Set null_vertex
CALL set_vertex(null_vertex,0_iwp,0.0_wp,0.0_wp)
!
!-- Some initializations
ddx = 1./dx
ddy = 1./dy
polygon_id = 0
obstacle_height = 0.
grid%checked = .FALSE.
grid(-3:-1,:)%checked = .TRUE.
grid(nx+1:nx+3,:)%checked = .TRUE.
grid(:,-3:-1)%checked = .TRUE.
grid(:,ny+1:ny+3)%checked = .TRUE.
grid%polygon_id = 0
!
!-- Open files and topography/building data
CALL netcdf_data_input_topo ( TRIM(input_trunk) )
END SUBROUTINE init
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Identifies all grid boxes that belong to a building and assigns a building
!> number to each grid box.
!> Method: Scans each grid point. If a grid point was not previously checked
!> and contains a building, it is added to a new polygon and marked as
!> checked. Then, all its neighbors that also contain a building are
!> added to the same polygon and marked as checked. All neighbors of
!> neighbors are subsequently found, added and checked until none are
!> left. Then, the initial scan continues, skipping already checked
!> grid points. Once a grid point with a new building is found, the
!> polygon_id increases and the grid point and all others that belong
!> to the same building are added as described above.
!> NOTE: This procedure will identify grid points that are only connected
!> diagonally (share only one point with each other) as connected and
!> have them belonging to the same building. This is necessary, as an
!> agent will not be able to traverse between these grid points and the
!> navigation mesh will therefore have to make him circumvent this
!> point.
!------------------------------------------------------------------------------!
SUBROUTINE identify_polygons
IMPLICIT NONE
INTEGER(iwp) :: ii !< local counter
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: jj !< local counter
INTEGER(iwp) :: jl !< local counter
INTEGER(iwp) :: gpil !< number of grid points in list
INTEGER(iwp) :: gpta !< number of grid points to add to grid_list
TYPE(grid_point), DIMENSION(1:7) :: add_to_grid_list !< grid points to be added to the list
TYPE(grid_point), DIMENSION(:), ALLOCATABLE :: dummy_grid_list !< dummy for reallocation of grid_list
TYPE(grid_point), DIMENSION(:), ALLOCATABLE :: grid_list !< list of grid points that belong to the current building but whose neighbors have not been checked yet
!
!-- Initialize wall_flags array: 1 where no buildings, 0 where buildings
wall_flags_0 = 1
DO i = 0, nx
DO j = 0, ny
IF ( obstacle_height(i,j) > 0 ) THEN
wall_flags_0(i,j) = 0
ENDIF
ENDDO
ENDDO
DEALLOCATE(obstacle_height)
polygon_counter = 0
gpil = 0
gpta = 0
ALLOCATE(grid_list(1:100))
!
!-- Declare all grid points that contain no buildings as already checked.
!-- This way, these points will be skipped in the following calculation and
!-- will have polygon_id = 0
DO i = 0, nx
DO j = 0, ny
IF ( BTEST( wall_flags_0(i,j), 0 ) ) THEN
grid(i,j)%checked = .TRUE.
ENDIF
ENDDO
ENDDO
!
!-- Check all grid points and process them
DO i = 0, nx
DO j = 0, ny
!
!-- If the current grid point has not been checked, mark it as checked.
!-- As it is the first point belonging to a new building, increase the
!-- polygon_id counter and associate the grid point with that id.
IF ( .NOT. grid(i,j)%checked ) THEN
polygon_counter = polygon_counter + 1
grid(i,j)%polygon_id = polygon_counter
grid(i,j)%checked = .TRUE.
!
!-- Check if any neighbors of the found grid point are part of a
!-- building too. If so, add them to the list of grid points
!-- that have to be checked and associate them with the same polygon
gpta = 0
DO ii = i-1, i+1
DO jj = j-1, j+1
IF ( ii == i .AND. jj == j ) CYCLE
IF ( .NOT. grid(ii,jj)%checked ) THEN
gpta = gpta + 1
add_to_grid_list(gpta)%i = ii
add_to_grid_list(gpta)%j = jj
ENDIF
ENDDO
ENDDO
!
!-- Change size of grid_list if it becomes too small
IF ( gpil + gpta > SIZE(grid_list) ) THEN
ALLOCATE(dummy_grid_list(1:gpil))
dummy_grid_list = grid_list(1:gpil)
DEALLOCATE(grid_list)
ALLOCATE(grid_list(1:2*(gpil+gpta)))
grid_list(1:gpil) = dummy_grid_list(1:gpil)
DEALLOCATE(dummy_grid_list)
ENDIF
!
!-- If there are grid points to add to grid_list, add them
IF ( gpta > 0 ) THEN
grid_list(gpil+1:gpil+gpta) = add_to_grid_list(1:gpta)
gpil = gpil + gpta
ENDIF
!
!-- Handle all grid points in grid_list until there are none left
DO WHILE (gpil>0)
il = grid_list(gpil)%i
jl = grid_list(gpil)%j
grid(il,jl)%polygon_id = polygon_counter
grid(il,jl)%checked = .TRUE.
!
!-- this grid point in the list is processed, so the number of
!-- grid points in the list can be reduced by one
gpil = gpil - 1
gpta = 0
!
!-- For the current grid point, check if any unchecked
!-- neighboring grid points also contain a building. All such
!-- grid points are added to the list of grid points to be
!-- handled in this loop
DO ii = il-1, il+1
DO jj = jl-1, jl+1
IF ( jj == jl .AND. ii == il ) CYCLE
IF ( .NOT. grid(ii,jj)%checked ) &
THEN
gpta = gpta + 1
add_to_grid_list(gpta)%i = ii
add_to_grid_list(gpta)%j = jj
ENDIF
ENDDO
ENDDO
!
!-- Change size of grid list if it becomes too small
IF ( gpil + gpta > SIZE(grid_list) ) THEN
ALLOCATE(dummy_grid_list(1:gpil))
dummy_grid_list = grid_list(1:gpil)
DEALLOCATE(grid_list)
ALLOCATE(grid_list(1:2*(gpil+gpta)))
grid_list(1:gpil) = dummy_grid_list(1:gpil)
DEALLOCATE(dummy_grid_list)
ENDIF
!
!-- If there are grid points to add to list, add them
IF ( gpta > 0 ) THEN
grid_list(gpil+1:gpil+gpta) = add_to_grid_list(1:gpta)
gpil = gpil + gpta
ENDIF
ENDDO
ENDIF
ENDDO
ENDDO
DEALLOCATE(grid_list)
!
!-- Set size of polygon array and initialize
ALLOCATE(polygons(1:polygon_counter))
polygons%nov = 0
END SUBROUTINE identify_polygons
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Identifies the corners of the PALM building topography and adds them to
!> a specific polygon for each building as vertices. This converts the gridded
!> building data into one polygon per building that contains the coordinates of
!> each inner and outer corner of that building as vertices.
!> A grid point contains an outer corner if it's part of a building and exactly
!> one of its horizontal and one of its vertical neighbors is also part of a
!> building (4 cases).
!> A grid point contains an inner corner if it's not part of a building and
!> exactly one of its horizontal, one of its diagonal and one of its vertical
!> neighbors are each part of a building and in turn neighbors
!> to each other (4 cases).
!------------------------------------------------------------------------------!
SUBROUTINE identify_corners
IMPLICIT NONE
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: p_id !< current polygon_id
!
!-- For all grid points, check whether it contains one or more corners
DO i = 0, nx
DO j = 0, ny
!
!-- First, check if grid contains topography and has a corner.
IF ( .NOT. BTEST( wall_flags_0(i,j), 0 ) ) THEN
!
!-- Corner at south left edge of grid cell
IF ( BTEST( wall_flags_0(i-1,j), 0 ) .AND. &
BTEST( wall_flags_0(i,j-1), 0 )) &
THEN
p_id = grid(i,j)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, i*dx, j*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at north left edge of grid cell
IF ( BTEST( wall_flags_0(i-1,j), 0 ) .AND. &
BTEST( wall_flags_0(i,j+1), 0 )) &
THEN
p_id = grid(i,j)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, i*dx, (j+1)*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at north right edge of grid cell
IF ( BTEST( wall_flags_0(i+1,j), 0 ) .AND. &
BTEST( wall_flags_0(i,j+1), 0 )) &
THEN
p_id = grid(i,j)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, (i+1)*dx, (j+1)*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at south right edge of grid cell
IF ( BTEST( wall_flags_0(i+1,j), 0 ) .AND. &
BTEST( wall_flags_0(i,j-1), 0 )) &
THEN
p_id = grid(i,j)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, (i+1)*dx, j*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Second, check if grid contains no topography and has a corner.
ELSE
!
!-- Corner at south left edge of grid cell
IF ( .NOT. BTEST( wall_flags_0(i-1,j), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i,j-1), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i-1,j-1), 0 ) ) &
THEN
p_id = grid(i-1,j-1)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, i*dx, j*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at north left edge of grid cell
IF ( .NOT. BTEST( wall_flags_0(i-1,j), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i,j+1), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i-1,j+1), 0 ) ) &
THEN
p_id = grid(i-1,j+1)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, i*dx, (j+1)*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at north right edge of grid cell
IF ( .NOT. BTEST( wall_flags_0(i+1,j), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i,j+1), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i+1,j+1), 0 ) ) &
THEN
p_id = grid(i+1,j+1)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, (i+1)*dx, (j+1)*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
!
!-- Corner at south right edge of grid cell
IF ( .NOT. BTEST( wall_flags_0(i+1,j), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i,j-1), 0 ) .AND. &
.NOT. BTEST( wall_flags_0(i+1,j-1), 0 ) ) &
THEN
p_id = grid(i+1,j-1)%polygon_id
polygons(p_id)%nov = polygons(p_id)%nov + 1
nov = polygons(p_id)%nov
CALL set_vertex(dummy_vertex, p_id, (i+1)*dx, j*dy)
CALL add_vertex_to_polygon(dummy_vertex, p_id, nov)
ENDIF
ENDIF
ENDDO
ENDDO
END SUBROUTINE identify_corners
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Initializes a vertex
!------------------------------------------------------------------------------!
SUBROUTINE set_vertex (in_vertex, p_id, x, y)
IMPLICIT NONE
INTEGER(iwp) :: p_id !< polygon ID
REAL(wp) :: x !< x-coordinate of vertex position
REAL(wp) :: y !< y-coordinate of vertex position
TYPE(vertex_type) :: in_vertex !< vertex to be set
in_vertex%delete = .FALSE.
in_vertex%x = x
in_vertex%y = y
END SUBROUTINE set_vertex
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Adds an existing vertex to the polygon with ID p_id at position in_nov
!------------------------------------------------------------------------------!
SUBROUTINE add_vertex_to_polygon ( in_vertex, p_id, in_nov)
IMPLICIT NONE
INTEGER(iwp) :: in_nov !< counter of vertex being added to polygon
INTEGER(iwp) :: p_id !< polygon ID
INTEGER(iwp) :: sop !< size of vertices array
TYPE(vertex_type) :: in_vertex !< vertex to be added
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: dummy_v_list !< for reallocation
polygon => polygons(p_id)
!
!-- Allocate and initialize the vertex array of the polygon, if necessary
IF ( .NOT. ALLOCATED(polygon%vertices) ) THEN
ALLOCATE(polygon%vertices(1:100))
polygon%vertices = null_vertex
ENDIF
!
!-- Adjust size of polygon, if necessary
sop = SIZE(polygon%vertices)
IF ( in_nov > sop ) THEN
ALLOCATE(dummy_v_list(1:sop))
dummy_v_list(1:sop) = polygon%vertices(1:sop)
DEALLOCATE(polygon%vertices)
ALLOCATE(polygon%vertices(1:2*sop))
polygon%vertices = null_vertex
polygon%vertices(1:sop) = dummy_v_list(1:sop)
DEALLOCATE(dummy_v_list)
ENDIF
polygon%vertices(in_nov) = in_vertex
END SUBROUTINE add_vertex_to_polygon
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Sorts the vertices of a polygon in a counter-clockwise fashion. During this
!> process, all vertices that are not part of the hull of the building
!> (inner courtyards) are deleted.
!------------------------------------------------------------------------------!
SUBROUTINE sort_polygon(i_p)
IMPLICIT NONE
LOGICAL :: starting_vertex_found
INTEGER(iwp) :: counter !< counter for potential starting vertices
INTEGER(iwp) :: id_neighbor !< final ID of neighboring vertex
INTEGER(iwp) :: id_neighbor1 !< ID of first potential neighbor
INTEGER(iwp) :: id_neighbor2 !< ID of second potential neighbor
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: i_p !< index of the current polygon
INTEGER(iwp) :: noc !< number of candidates
INTEGER(iwp) :: nosv !< number of sorted vertices
INTEGER(iwp) :: xe !< x-end-index for building search
INTEGER(iwp) :: xs !< x-start-index for building search
INTEGER(iwp) :: ye !< y-end-index for building search
INTEGER(iwp) :: ys !< y-start-index for building search
INTEGER, DIMENSION(:), ALLOCATABLE :: candidate_id !< ID of the potential neighbors stored in 'candidates'
INTEGER, DIMENSION(:), ALLOCATABLE :: dummy_id_arr !< used for resizing
REAL(wp) :: dist !< distance of one vertex to its neighbor
REAL(wp) :: m_x !< min/max x-value of polygon used for starting vertex
REAL(wp) :: m_y !< min/max y-value of polygon used for starting vertex
TYPE(vertex_type) :: current_v !< current vertex
TYPE(vertex_type) :: dummy_vertex !< dummy vertex for reordering
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: candidates !< potential neighbors of the current vertex
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: dummy_vertex_arr !< used for resizing
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: sorted_p !< vertices that have been sorted
starting_vertex_found = .FALSE.
ALLOCATE(sorted_p(1:nov))
sorted_p(1:nov) = polygon%vertices(1:nov)
!
!-- Identify a vertex that is certainly a part of the outer hull of the
!-- current polygon: Get rightmost border of polygon (or if that
!-- coincides with model border, leftmost) border. Then of those points,
!-- get northmost (or if that coincides with model domain border, southmost).
!-- This identifies exactly one point that is then set to the first index.
counter = 0
IF ( MAXVAL(sorted_p%x) < nx*dx ) THEN
m_x = MAXVAL(sorted_p%x)
ELSE
m_x = MINVAL(sorted_p%x)
ENDIF
DO il = 1, nov
IF ( sorted_p(il)%x == m_x ) THEN
counter = counter + 1
dummy_vertex = sorted_p(il)
sorted_p(il) = sorted_p(counter)
sorted_p(counter) = dummy_vertex
ENDIF
ENDDO
IF ( MAXVAL(sorted_p(1:counter)%y) < ny*dy ) THEN
m_y = MAXVAL(sorted_p(1:counter)%y)
ELSE
m_y = MINVAL(sorted_p(1:counter)%y)
ENDIF
DO il = 1, counter
IF ( sorted_p(il)%y == m_y ) THEN
dummy_vertex = sorted_p(il)
sorted_p(il) = sorted_p(1)
sorted_p(1) = dummy_vertex
starting_vertex_found = .TRUE.
EXIT
ENDIF
ENDDO
!
!-- If no starting vertex was found for the current polygon, it will be
!-- deleted and an error message thrown
IF ( .NOT. starting_vertex_found ) THEN
WRITE(*,'(A,/,A,X,I6,/,A)') &
'An error occured during polygon sorting:', &
'no starting vertex could be found for polygon', &
i_p, 'This polygon contains the following vertices (x/y)'
DO il = 1, nov
WRITE(*,'(4X,F8.1,X,F8.1)') &
polygon%vertices(il)%x, polygon%vertices(il)%x
ENDDO
WRITE(*,'(A,/,A)') &
'This polygon will be skipped during sorting and deleted',&
'For details on the procedure, see SUBROUTINE sort_polygon.'
polygon%vertices%delete = .TRUE.
polygons(i_p)%nov = 0
CALL delete_empty_polygons
!
!-- Find the unique neighbor of the current vertex. For this, first
!-- determine all possible candidates. Of those, keep only the ones that
!-- are connected to the current vertex along a building edge (the polygon
!-- is sorted counter-clockwise. Therefore, the building is always on the
!-- left-hand side of the connecting line from the current vertex to its
!-- potential neighbor). This leaves a maximum of two possible neighbors.
!-- This is only the case if the current vertex is the point that diagonally
!-- connects two parts of the same building. In that case, the vertex that
!-- lies to the right of the connecting line between the previous and
!-- current vertex is the neighbor.
ELSE
DO nosv = 1, nov
current_v = sorted_p(nosv)
noc = 0
ALLOCATE(candidates(1:100), candidate_id(1:100))
!
!-- Find all candidates that could be neighbors of current vertex:
!-- these are those vertices that share the same x- or y-coordinate
!-- with the current vertex, as the vertices are all inner and outer
!-- corners of the gridded building data
IF ( nosv < nov ) THEN
DO il = nosv+1, nov
IF ( current_v%x == sorted_p(il)%x .OR. &
current_v%y == sorted_p(il)%y) &
THEN
!
!-- If necessary, resize arrays for candidates
IF ( noc >= SIZE(candidates) ) THEN
ALLOCATE(dummy_vertex_arr(1:noc), dummy_id_arr(1:noc))
dummy_vertex_arr(1:noc) = candidates(1:noc)
dummy_id_arr(1:noc) = candidate_id(1:noc)
DEALLOCATE(candidates, candidate_id)
ALLOCATE(candidates(1:2*noc), candidate_id(1:2*noc))
candidates(1:noc) = dummy_vertex_arr(1:noc)
candidate_id(1:noc) = dummy_id_arr(1:noc)
DEALLOCATE(dummy_vertex_arr, dummy_id_arr)
ENDIF
noc = noc +1
candidates(noc) = sorted_p(il)
candidate_id(noc) = il
ENDIF
ENDDO
ENDIF
!
!-- Check which one of the candidates is the neighbor of the current
!-- vertex. This is done by several tests that would exclude the
!-- candidate from being the neighbor. Each successful test will
!-- therefore result in a cycle to the next candidate. Only if all
!-- all tests fail, is the candidate one of a maximum of two possible
!-- neighbors.
id_neighbor1 = -999
id_neighbor2 = -999
DO il = 1, noc
!
!-- Exclude the possibility of a vertex with the same coordinates
!-- being chosen as the neighbor. (dist < .9*dx)
!-- NOTE: this could happen, if part of a building is only connected
!-- to the rest of the building diagonally. In that case, the
!-- same point is added to the polygon twice. This is necessary
!-- and not redundant! Two such points can never be neighbors.
!-- Example: the north right corner of grid point i,j
!-- AND the south left corner of grid point i+1,j+1.
!-- See SUBROUTINE identify_corners for the identification
!-- method.
!-- Also, exclude a connection back to the coordinates of the
!-- previous vertex.
dist = SQRT( (candidates(il)%x - current_v%x)**2 + &
(candidates(il)%y - current_v%y)**2 )
IF ( nosv > 1 ) THEN
IF ( dist < .9*dx .OR. &
(sorted_p(nosv-1)%x == candidates(il)%x .AND. &
sorted_p(nosv-1)%y == candidates(il)%y) ) &
THEN
CYCLE
ENDIF
ENDIF
!
!-- Check if there is a building all along only the left-hand side
!-- of the connecting line from current vertex to potential neighbor
!-- (4 cases)
!-- First: for vertical connection
IF ( candidates(il)%x == current_v%x ) THEN
xs = NINT(current_v%x*ddx)-1
xe = xs + 1
!
!-- Case 1: ys < ye, edge from south to north, building must be
!-- exclusively in all grid cells left of the edge
IF ( current_v%y < candidates(il)%y ) THEN
ys = NINT(current_v%y*ddy)
ye = NINT(candidates(il)%y*ddy)-1
IF ( .NOT.( ALL( .NOT. BTEST( wall_flags_0(xs,ys:ye), 0))&
.AND.( ALL( BTEST( wall_flags_0(xe,ys:ye), 0 ) ) )))&
THEN
CYCLE
ENDIF
!
!-- Case 2: ys > ye, edge from north to south, building must be
!-- exclusively in all grid cells right of the edge
ELSEIF ( current_v%y > candidates(il)%y ) THEN
ys = NINT(current_v%y*ddy)-1
ye = NINT(candidates(il)%y*ddy)
IF ( .NOT.( ALL( .NOT. BTEST( wall_flags_0(xe,ye:ys), 0))&
.AND.( ALL( BTEST( wall_flags_0(xs,ye:ys), 0 ) ) )))&
THEN
CYCLE
ENDIF
ENDIF
!
!-- Horizontal connection
ELSEIF ( candidates(il)%y == current_v%y ) THEN
ys = NINT(current_v%y*ddy)-1
ye = ys + 1
!
!-- Case 3: xs > xe, edge from right to left, building must be
!-- exclusively in all grid cells south of the edge
IF ( current_v%x > candidates(il)%x ) THEN
xs = NINT(current_v%x*ddx)-1
xe = NINT(candidates(il)%x*ddx)
IF ( .NOT.( ALL( .NOT. BTEST( wall_flags_0(xe:xs,ys), 0))&
.AND.( ALL( BTEST( wall_flags_0(xe:xs,ye), 0 ) ) )))&
THEN
CYCLE
ENDIF
!
!-- Case 4: xs < xe, edge from left to right, building must be
!-- exclusively in all grid cells north of the edge
ELSEIF ( current_v%x < candidates(il)%x ) THEN
xs = NINT(current_v%x*ddx)
xe = NINT(candidates(il)%x*ddx)-1
IF ( .NOT.( ALL( .NOT. BTEST( wall_flags_0(xs:xe,ye), 0))&
.AND.( ALL( BTEST( wall_flags_0(xs:xe,ys), 0 ) ) )))&
THEN
CYCLE
ENDIF
ENDIF
ENDIF
!
!-- After the tests, only two potential neighbors are possible. The
!-- one found first will get id_neighbor1, the possible 2nd one will
!-- get id_neighbor2
IF ( id_neighbor1 == -999 ) THEN
id_neighbor1 = candidate_id(il)
ELSEIF ( id_neighbor1 /= -999 .AND. &
( sorted_p(id_neighbor1)%x /= candidates(il)%x ) .OR. &
( sorted_p(id_neighbor1)%y /= candidates(il)%y ) ) &
THEN
id_neighbor2 = candidate_id(il)
ENDIF
ENDDO
!
!-- If two potential neighbors were found, determine the one that is on
!-- the right hand side of the line connecting the current and previous
!-- vertex. It is the real neighbor.
IF ( id_neighbor2 /= -999 .AND. nosv > 1 ) THEN
IF ( is_right(sorted_p(nosv-1)%x,sorted_p(nosv-1)%y, &
current_v%x,current_v%y, &
sorted_p(id_neighbor1)%x,sorted_p(id_neighbor1)%y) )&
THEN
id_neighbor = id_neighbor1
ELSEIF ( is_right(sorted_p(nosv-1)%x,sorted_p(nosv-1)%y, &
current_v%x,current_v%y, &
sorted_p(id_neighbor2)%x,sorted_p(id_neighbor2)%y) )&
THEN
id_neighbor = id_neighbor2
ENDIF
ELSE
id_neighbor = id_neighbor1
ENDIF
!
!-- Put the found neighbor at next index in sorted array and move the
!-- unsorted vertices back one index. This way, only yet unsorted
!-- vertices are eligible to be candidates during the next iteration.
IF (id_neighbor /= nosv + 1 .AND. id_neighbor /= -999) THEN
dummy_vertex = sorted_p(id_neighbor)
sorted_p(nosv+2:id_neighbor) = sorted_p(nosv+1:id_neighbor-1)
sorted_p(nosv+1) = dummy_vertex
!
!-- If no neighbor was found, sorting is done for this polygon
ELSEIF ( id_neighbor == -999 ) THEN
DEALLOCATE(candidates,candidate_id)
EXIT
ENDIF
DEALLOCATE(candidates,candidate_id)
ENDDO
!
!-- Sorting is done. Reduce size (which means get rid of vertices
!-- that are not part of the outer hull of the building: holes)
!-- of sorted polygon and put it back in polygon%vertices.
!-- Also add first vertex to the end of polygon and last vertex
!-- before the beginning of polygon.
DEALLOCATE(polygon%vertices)
ALLOCATE(polygon%vertices(0:nosv+1))
polygon%vertices(1:nosv) = sorted_p(1:nosv)
polygon%vertices(0) = sorted_p(nosv)
polygon%vertices(nosv+1) = sorted_p(1)
polygons(i_p)%nov = nosv
nov = polygons(i_p)%nov
DEALLOCATE(sorted_p)
ENDIF
END SUBROUTINE sort_polygon
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reduces the number of vertices in a polygon using the
!> Douglas-Poiker-Algorithm (1973)
!------------------------------------------------------------------------------!
RECURSIVE SUBROUTINE simplify_polygon( id_s, id_e, tol )
IMPLICIT NONE
INTEGER(iwp) :: max_dist_ind !< Index of vertex with maximum distance
INTEGER(iwp) :: il !< counter
INTEGER(iwp) :: id_s !< End index in polygon
INTEGER(iwp) :: id_e !< End index in polygon
REAL(wp) :: max_dist !< Maximum distance from line
REAL(wp) :: dum_dist !< Distance from line: dummy
REAL(wp) :: tol !< factor that determines how far a vertex can be from the polygon approximation so that the approximation is still accepted
max_dist = 0.
max_dist_ind = -999999
!
!-- Find vertex with max distance to id_s and id_e
DO il = id_s + 1, id_e -1
dum_dist = dist_point_to_edge(polygon%vertices(id_s)%x, &
polygon%vertices(id_s)%y, &
polygon%vertices(id_e)%x, &
polygon%vertices(id_e)%y, &
polygon%vertices(il)%x, &
polygon%vertices(il)%y)
IF ( dum_dist > max_dist ) THEN
max_dist = dum_dist
max_dist_ind = il
ENDIF
ENDDO
IF ( max_dist > tol ) THEN
CALL simplify_polygon( id_s, max_dist_ind, tol )
CALL simplify_polygon( max_dist_ind, id_e, tol )
ELSE
polygon%vertices(id_s+1:id_e-1)%delete = .TRUE.
ENDIF
END SUBROUTINE simplify_polygon
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Checks if a vertex of a polygon is inside another polygon and if so, deletes
!> it. The check is done using the crossing number algorithm. If a straight
!> ray starting at a point crosses the borders of one polygon an odd
!> number of times, the point is inside that polygon.
!> This algorithm detects buildings that are completely surrounded by
!> another building. They can be deleted since they can never be navigated.
!> TODO: Maybe add a flag to turn this off and on as it might not be needed.
!> also, if the domain has buildings at all boundary points, there would
!> only be one giant building and everything in it deleted. So nothing
!> could be navigated. relevant?!
!------------------------------------------------------------------------------!
SUBROUTINE inside_other_polygon( i_p )
IMPLICIT NONE
LOGICAL :: exit_flag !< flag to exit loops if an odd crossing number was found for any of a polygons vertices
INTEGER(iwp) :: cn !< number of crossings
INTEGER(iwp) :: i_p !< index of current polygon
INTEGER(iwp) :: il !< index of tested polygon
INTEGER(iwp) :: nov_test !< no. of vertices of test-polygon
INTEGER(iwp) :: ref_vert !< vertex currently being tested if it is inside another polygon
INTEGER(iwp) :: test_edge !< index of edge being tested
REAL(wp) :: px !< x-coord of the point at the crossing of the ray and the vertex
REAL(wp) :: xe !< x-coordinate of end point of edge
REAL(wp) :: xr !< x-coordinate of reference point
REAL(wp) :: xs !< x-coordinate of start point of edge
REAL(wp) :: ye !< y-coordinate of end point of edge
REAL(wp) :: yr !< y-coordinate of reference point
REAL(wp) :: ys !< y-coordinate of start point of edge
TYPE(polygon_type), POINTER :: test_pol !< Polygon to be tested
exit_flag = .FALSE.
!
!-- Loop over all polygons other than the one being tested
DO il = 1, polygon_counter
IF ( il == i_p ) CYCLE
test_pol => polygons(il)
nov_test = polygons(il)%nov
!
!-- Inclusion test is done for every vertex of the polygon
DO ref_vert = 1, nov
cn = 0
xr = polygon%vertices(ref_vert)%x
yr = polygon%vertices(ref_vert)%y
!
!-- All edges of the every polygon il is tested for ray crossing
DO test_edge = 1, nov_test
!-- It is tested wether the current edge crosses a ray that extends
!-- from the current point to the right indefinitely.
!-- Check if start point of edge is lower than end point. If they
!-- are the same, ignore, since horizontal edges are excluded
IF ( test_pol%vertices(test_edge)%y < &
test_pol%vertices(test_edge+1)%y ) &
THEN
xs = test_pol%vertices(test_edge)%x
xe = test_pol%vertices(test_edge+1)%x
ys = test_pol%vertices(test_edge)%y
ye = test_pol%vertices(test_edge+1)%y
ELSEIF ( test_pol%vertices(test_edge)%y > &
test_pol%vertices(test_edge+1)%y ) &
THEN
xs = test_pol%vertices(test_edge+1)%x
xe = test_pol%vertices(test_edge)%x
ys = test_pol%vertices(test_edge+1)%y
ye = test_pol%vertices(test_edge)%y
ELSE
CYCLE
ENDIF
!
!-- Only such edges where the starting point of the edge is south of
!-- (or equal to) the reference point and the end point is north of
!-- it are relevant. Note: an edge includes its southern endpoint
!-- and excludes its northern endpoint.
IF ( .NOT. (ys <= yr .AND. ye > yr )) CYCLE
!
!-- Only edges that are crossed on the right side of the reference
!-- point are relevant, those on the left are ignored
IF ( xs <= xr .AND. xe <= xr ) CYCLE
IF ( ( xs <= xr .AND. xe >= xr ) .OR. &
( xs >= xr .AND. xe <= xr ) ) &
THEN
px = xe - (xe-xs)*(ye-yr)/(ye-ys)
IF ( px <= xr ) CYCLE
ENDIF
!
!-- If none of the previous if clauses were true, a crossing with
!-- an eligible edge was found and the count increases
cn = cn + 1
ENDDO
!
!-- If the number of crossings is odd, the point is inside another
!-- polyon. The polygon associated with the point will be deleted
IF ( MOD(cn, 2) /= 0 ) THEN
exit_flag = .TRUE.
EXIT
ENDIF
ENDDO
IF ( exit_flag ) EXIT
ENDDO
IF ( exit_flag ) polygon%vertices%delete = .TRUE.
END SUBROUTINE inside_other_polygon
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Deletes thoses vertices that are marked for deletion (%delete flag) and
!> resizes the polygon
!------------------------------------------------------------------------------!
SUBROUTINE delete_extra_vertices (i_p)
IMPLICIT NONE
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: vcounter !< vertex counter
INTEGER(iwp) :: i_p !< polygon ID
TYPE(vertex_type), DIMENSION(:), ALLOCATABLE :: dummy_pol !< Temporarily stores non-deleted vertices
ALLOCATE(dummy_pol(1:nov))
vcounter = 0
!
!-- Check all vertices and only keep those not marked for deletion
DO il = 1, nov
IF ( .NOT. polygon%vertices(il)%delete ) THEN
vcounter = vcounter + 1
dummy_pol(vcounter) = polygon%vertices(il)
ENDIF
ENDDO
!
!-- Set new number of vertices in the polygon
nov = vcounter
polygons(i_p)%nov = nov
!
!-- Resize
DEALLOCATE(polygon%vertices)
ALLOCATE(polygon%vertices(0:nov+1))
polygon%vertices(1:nov) = dummy_pol(1:nov)
polygon%vertices(0) = polygon%vertices(nov)
polygon%vertices(nov+1) = polygon%vertices(1)
DEALLOCATE(dummy_pol)
END SUBROUTINE delete_extra_vertices
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Deletes polygons that contain no vertices (happens for those polygons that
!> were entirely encompassed by another polygon)
!------------------------------------------------------------------------------!
SUBROUTINE delete_empty_polygons
IMPLICIT NONE
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: pc !< number of nonempty polygons
INTEGER(iwp) :: sv !< size of vertex array
TYPE(polygon_type), DIMENSION(:), ALLOCATABLE :: dummy_polygons !< temporarily stores non-deletd polygons
pc = 0
sv = 0
ALLOCATE( dummy_polygons(1:polygon_counter) )
!
!-- Keep only those polygons that contain any vertices, skip the rest
DO il = 1, polygon_counter
IF ( polygons(il)%nov > 0 ) THEN
pc = pc + 1
sv = SIZE(polygons(il)%vertices)
ALLOCATE(dummy_polygons(pc)%vertices(0:sv-1))
dummy_polygons(pc) = polygons(il)
ENDIF
ENDDO
polygon_counter = pc
!
!-- Resize polygon array
DEALLOCATE(polygons)
ALLOCATE(polygons(1:polygon_counter))
DO il = 1, polygon_counter
!
!-- give each %vertices array the correct size and information
sv = SIZE(dummy_polygons(il)%vertices)
polygons(il)%nov = sv - 2
ALLOCATE(polygons(il)%vertices(0:sv-1))
polygons(il) = dummy_polygons(il)
ENDDO
DEALLOCATE(dummy_polygons)
END SUBROUTINE delete_empty_polygons
END MODULE polygon_creation
MODULE mesh_creation
USE kinds
USE mod_functions
USE variables
CONTAINS
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Creates the navigation mesh:
!> 1) Finds eligible vertices (those that are locally convex)
!> 2) Adds them to the mesh
!> 3) Adds connections between mesh points if they are in line of sight
!> of each other and the connecting line does not point into either of
!> the originating polygons (this is known as a visibility graph)
!------------------------------------------------------------------------------!
SUBROUTINE create_nav_mesh
IMPLICIT NONE
LOGICAL :: add !< flag for second cycle of add loop
LOGICAL :: intersection_found !< flag to indicate a found intersection
INTEGER(iwp) :: cmp !< counter: current mesh point
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: jl !< local counter
INTEGER(iwp) :: pid !< polygon id of current mesh point
INTEGER(iwp) :: pid_t !< polygon id of tested mesh point
INTEGER(iwp) :: pl !< polygon counter
INTEGER(iwp) :: vid !< vertex id of current mesh point
INTEGER(iwp) :: vid_t !< vertex id of tested mesh point
INTEGER(iwp) :: vl !< vertex counter
REAL(wp) :: left !< counter: current mesh point
REAL(wp) :: v1x !< x-coordinate of test vertex 1 for intersection test
REAL(wp) :: v1y !< y-coordinate of test vertex 1 for intersection test
REAL(wp) :: v2x !< x-coordinate of test vertex 2 for intersection test
REAL(wp) :: v2y !< y-coordinate of test vertex 2 for intersection test
REAL(wp) :: x !< x-coordinate of current mesh point
REAL(wp) :: x_t !< x-coordinate of tested mesh point
REAL(wp) :: y !< y-coordinate of current mesh point
REAL(wp) :: y_t !< y-coordinate of tested mesh point
REAL(wp) :: corner_x !< x-coordinate of shifted corner
REAL(wp) :: corner_x_e !< x-coordinate of end of corner gate
REAL(wp) :: corner_y !< y-coordinate of shifted corner
REAL(wp) :: corner_y_e !< y-coordinate of end of corner gate
REAL(wp) :: t_start !< CPU measure: start
REAL(wp) :: t_inter !< CPU measure: output test time
REAL(wp) :: t_inter1 !< CPU measure: output test time
REAL(wp) :: t_end !< CPU measure: end
REAL(wp) :: t_left !< CPU measure: estimate for time left
REAL(wp) :: t_done !< CPU measure: elapsed time
REAL(wp) :: percent_done !< CPU measure: proportion of mesh points checked
!
!-- Add all convex vertices to the mesh.
!-- DO loop will be executed twice. Once to count the mesh points to be
!-- added and allocate the mesh point array, the second time (add == .TRUE.)
!-- to fill the mesh point array.
WRITE(*,'(X,A)') 'Adding polygon vertices to mesh ...'
add = .FALSE.
DO
cmp = 0
DO il = 1, polygon_counter
polygon => polygons(il)
nov = polygons(il)%nov
DO jl = 1, nov
!
!-- In a polygon that is sorted counter-clockwise, if the next vertex
!-- is left of the line connecting the previous and the current vertex,
!-- the current vertex is locally convex.
IF ( is_left(polygon%vertices(jl-1)%x,polygon%vertices(jl-1)%y, &
polygon%vertices(jl)%x,polygon%vertices(jl)%y, &
polygon%vertices(jl+1)%x,polygon%vertices(jl+1)%y) ) &
THEN
corner_x = polygon%vertices(jl)%x
corner_y = polygon%vertices(jl)%y
!
!-- Create end point for corner navigation
IF ( add ) THEN
CALL shift_corner_outward( &
polygon%vertices(jl-1)%x, polygon%vertices(jl-1)%y,&
polygon%vertices(jl+1)%x, polygon%vertices(jl+1)%y,&
polygon%vertices(jl)%x, polygon%vertices(jl)%y, &
corner_x_e, corner_y_e, 1._wp )
ENDIF
!
!-- Disregard corners outside of the domain
IF ( corner_x<=(nx+1)*dx .AND. corner_x>=0 .AND. &
corner_y<=(ny+1)*dy .AND. corner_y>=0) &
THEN
cmp = cmp + 1
IF ( add ) THEN
CALL set_mesh_point( mesh(cmp), il, jl, &
corner_x, corner_y, &
corner_x_e, corner_y_e )
ENDIF
ENDIF
ENDIF
ENDDO
ENDDO
IF ( add ) EXIT
add = .TRUE.
ALLOCATE( mesh(1:cmp) )
ENDDO
WRITE(*,'(6X,A,X,I10,X,A,/)') 'Done. Added',cmp,'vertices to mesh.'
WRITE(*,'(X,A)') 'Establishing connections in mesh ...'
!
!-- CPU measurement
CALL CPU_TIME(t_start)
CALL CPU_TIME(t_inter)
DO il = 1, cmp
!-- Output status of processing
CALL CPU_TIME(t_inter1)
IF ( t_inter1 - t_inter > 4. ) THEN
t_done = (t_inter1-t_start)/60.
percent_done = REAL(il)/cmp*100.
t_left = t_done/percent_done*(100-percent_done)
WRITE(*,'(3X,2(A,I8),A,F6.2,2(A,F7.1),A,I10)') &
'Mesh point ',il,' of ' ,cmp, &
': ' ,percent_done, &
' % || elapsed time : ' ,t_done, &
' min || ETA: ' ,t_left, &
' min || number of connections found: ',number_of_connections
CALL CPU_TIME(t_inter)
ENDIF
x = mesh(il)%x
y = mesh(il)%y
pid = mesh(il)%polygon_id
vid = mesh(il)%vertex_id
DO jl = 1, cmp
!
!-- No mesh point can be connected to itself
IF ( il == jl ) CYCLE
x_t = mesh(jl)%x
y_t = mesh(jl)%y
pid_t = mesh(jl)%polygon_id
vid_t = mesh(jl)%vertex_id
!
!-- Cycle, if a connection had already been established
IF ( ANY(mesh(jl)%connected_vertices == il) ) CYCLE
!
!-- If the distance between two nodes is larger than 600 m,
!-- no connection will be made since there will typically no be such
!-- long, straight ways in a city that a pedestrian will walk
IF ( SQRT((x_t-x)**2 +(y_t-y)**2) > 400. ) CYCLE
!
!-- If the connecting line between two mesh points points into either
!-- or both of the corresponding polygons, no connection will be
!-- established between the two points. This is the case if the
!-- previous (next) vertex of the polygon is right of the connecting
!-- line and the next (previous) vertex of the polygon is left of the
!-- connecting line. This is checked for both polygons.
IF ( ((is_left(x_t,y_t,x,y,polygons(pid)%vertices(vid-1)%x, &
polygons(pid)%vertices(vid-1)%y) &
.AND. is_right(x_t,y_t,x,y,polygons(pid)%vertices(vid+1)%x, &
polygons(pid)%vertices(vid+1)%y) ) &
.OR. (is_right(x_t,y_t,x,y,polygons(pid)%vertices(vid-1)%x, &
polygons(pid)%vertices(vid-1)%y) &
.AND. is_left(x_t,y_t,x,y,polygons(pid)%vertices(vid+1)%x, &
polygons(pid)%vertices(vid+1)%y)) ) &
.OR. ((is_left(x,y,x_t,y_t,polygons(pid_t)%vertices(vid_t-1)%x, &
polygons(pid_t)%vertices(vid_t-1)%y) &
.AND. is_right(x,y,x_t,y_t,polygons(pid_t)%vertices(vid_t+1)%x, &
polygons(pid_t)%vertices(vid_t+1)%y) ) &
.OR. (is_right(x,y,x_t,y_t,polygons(pid_t)%vertices(vid_t-1)%x, &
polygons(pid_t)%vertices(vid_t-1)%y) &
.AND. is_left(x,y,x_t,y_t,polygons(pid_t)%vertices(vid_t+1)%x, &
polygons(pid_t)%vertices(vid_t+1)%y)) ) ) &
THEN
CYCLE
ENDIF
!
!-- For each edge of each polygon, check if it intersects with the
!-- potential connection. If so, no connection can be made
!-- THIS IS THE BOTTLENECK OF THE PROGRAM
intersection_found = .FALSE.
DO pl = pid, polygon_counter
DO vl = 1, polygons(pl)%nov
v1x = polygons(pl)%vertices(vl)%x
v1y = polygons(pl)%vertices(vl)%y
v2x = polygons(pl)%vertices(vl+1)%x
v2y = polygons(pl)%vertices(vl+1)%y
intersection_found = intersect(x,y,x_t,y_t,v1x,v1y,v2x,v2y)
IF ( intersection_found ) EXIT
ENDDO
IF ( intersection_found ) EXIT
ENDDO
IF ( intersection_found ) CYCLE
DO pl = pid, 1, -1
IF ( pl == pid ) CYCLE
DO vl = 1, polygons(pl)%nov
v1x = polygons(pl)%vertices(vl)%x
v1y = polygons(pl)%vertices(vl)%y
v2x = polygons(pl)%vertices(vl+1)%x
v2y = polygons(pl)%vertices(vl+1)%y
intersection_found = intersect(x,y,x_t,y_t,v1x,v1y,v2x,v2y)
IF ( intersection_found ) EXIT
ENDDO
IF ( intersection_found ) EXIT
ENDDO
IF ( intersection_found ) CYCLE
!
!-- If neither of the above two test was true, a connection will be
!-- established between the two mesh points.
number_of_connections = number_of_connections + 1
CALL add_connection(mesh(il),jl, mesh(jl))
CALL add_connection(mesh(jl),il, mesh(il))
ENDDO
ENDDO
!
!-- Adapt connected_vertices arrays
DO il = 1, cmp
CALL reduce_connections(mesh(il))
ENDDO
CALL CPU_TIME(t_end)
!
!-- Output to terminal
WRITE(*,'(6X,A,I10,A)') 'Done. Established ',number_of_connections, &
' connections in mesh'
WRITE(*,'(6X,A,F10.1,A)') 'Time needed for calculation: ', &
t_end-t_start,' seconds'
END SUBROUTINE create_nav_mesh
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Initializes a point of the navigation mesh
!------------------------------------------------------------------------------!
SUBROUTINE set_mesh_point (in_mp,pid,vid,x,y,x_s,y_s)
IMPLICIT NONE
INTEGER(iwp) :: pid !< polygon ID
INTEGER(iwp) :: vid !< vertex ID
REAL(wp) :: x !< x-value of mesh point for path calculation
REAL(wp) :: x_s !< x-value shifted outward from corner
REAL(wp) :: y !< y-value of mesh point for path calculation
REAL(wp) :: y_s !< y-value shifted outward from corner
TYPE(mesh_point) :: in_mp !< mesh point to be created
in_mp%origin_id = -1
in_mp%polygon_id = pid
in_mp%vertex_id = vid
in_mp%cost_so_far = 1.d12
in_mp%x = x
in_mp%y = y
in_mp%x_s = x_s
in_mp%y_s = y_s
in_mp%noc = 0
ALLOCATE(in_mp%connected_vertices(1:100), &
in_mp%distance_to_vertex(1:100))
in_mp%connected_vertices = -999
in_mp%distance_to_vertex = -999.
END SUBROUTINE set_mesh_point
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Shifts a corner (middle one of three consecutive points a, b and p) outward
!> by a given length along the angle bisector. Stores the result to res_x/res_y
!------------------------------------------------------------------------------!
SUBROUTINE shift_corner_outward ( a_x, a_y, b_x, b_y, p_x, p_y, res_x, &
res_y, shift )
IMPLICIT NONE
REAL(wp) :: a_x !< x-value of point A
REAL(wp) :: a_y !< y-value of point A
REAL(wp) :: abs_ap !< distance from A to P
REAL(wp) :: abs_bp !< distance from B to P
REAL(wp) :: abs_co !< length of angle bisector
REAL(wp) :: b_x !< x-value of point B
REAL(wp) :: b_y !< y-value of point B
REAL(wp) :: eap_x !< x-value of unit vector from A to P
REAL(wp) :: eap_y !< y-value of unit vector from A to P
REAL(wp) :: ebp_x !< x-value of unit vector from B to P
REAL(wp) :: ebp_y !< y-value of unit vector from B to P
REAL(wp) :: p_x !< x-value of point P
REAL(wp) :: p_y !< y-value of point P
REAL(wp) :: res_x !< x-value of result
REAL(wp) :: res_y !< y-value of result
REAL(wp) :: shift !< distance of shift in meters
!
!-- Get unit vector from previous to current vertex
eap_x = p_x - a_x
eap_y = p_y - a_y
abs_ap = SQRT(eap_x**2+eap_y**2)
eap_x = eap_x/abs_ap
eap_y = eap_y/abs_ap
!
!-- Get unit vector from next to current vertex
ebp_x = p_x - b_x
ebp_y = p_y - b_y
abs_bp = SQRT(ebp_x**2+ebp_y**2)
ebp_x = ebp_x/abs_bp
ebp_y = ebp_y/abs_bp
!
!-- Add previous two vectors to get angle bisector of corner.
!-- Then, set its length to shift and add to original vertex
!-- vector to shift it outward
res_x = eap_x + ebp_x
res_y = eap_y + ebp_y
abs_co = SQRT(res_x**2+res_y**2)
res_x = shift*res_x/abs_co + p_x
res_y = shift*res_y/abs_co + p_y
END SUBROUTINE shift_corner_outward
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Adds a connection between two points of the navigation mesh
!> (one-way: in_mp1 to in_mp2)
!------------------------------------------------------------------------------!
SUBROUTINE add_connection (in_mp1,id2,in_mp2)
IMPLICIT NONE
LOGICAL :: connection_established !< Flag to indicate if connection has already been established
INTEGER(iwp) :: id2 !< ID of in_mp2
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: noc1 !< number of connections in in_mp1
INTEGER, DIMENSION(:), ALLOCATABLE :: dum_cv !< dummy array for connected_vertices
REAL(wp) :: dist !< Distance between the two points
REAL(wp), DIMENSION(:), ALLOCATABLE :: dum_dtv
TYPE(mesh_point) :: in_mp1 !< mesh point that gets a new connection
TYPE(mesh_point) :: in_mp2 !< mesh point in_mp1 will be connected to
connection_established = .FALSE.
!
!-- Check if connection has already been established
noc1 = SIZE(in_mp1%connected_vertices)
DO il = 1, in_mp1%noc
IF ( in_mp1%connected_vertices(il) == id2 ) THEN
connection_established = .TRUE.
EXIT
ENDIF
ENDDO
IF ( .NOT. connection_established ) THEN
!
!-- Resize arrays, if necessary
IF ( in_mp1%noc >= noc1 ) THEN
ALLOCATE( dum_cv(1:noc1),dum_dtv(1:noc1) )
dum_cv = in_mp1%connected_vertices
dum_dtv = in_mp1%distance_to_vertex
DEALLOCATE( in_mp1%connected_vertices, in_mp1%distance_to_vertex )
ALLOCATE( in_mp1%connected_vertices(1:2*noc1), &
in_mp1%distance_to_vertex(1:2*noc1) )
in_mp1%connected_vertices = -999
in_mp1%distance_to_vertex = -999.
in_mp1%connected_vertices(1:noc1) = dum_cv
in_mp1%distance_to_vertex(1:noc1) = dum_dtv
ENDIF
!
!-- Add connection
in_mp1%noc = in_mp1%noc+1
dist = SQRT( (in_mp1%x - in_mp2%x)**2 + (in_mp1%y - in_mp2%y)**2 )
in_mp1%connected_vertices(in_mp1%noc) = id2
in_mp1%distance_to_vertex(in_mp1%noc) = dist
ENDIF
END SUBROUTINE add_connection
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Reduces the size of connection array to the amount of actual connections
!> after all connetions were added
!------------------------------------------------------------------------------!
SUBROUTINE reduce_connections (in_mp)
IMPLICIT NONE
INTEGER(iwp) :: il !< Local counter
INTEGER(iwp) :: noc !< Number of connections
INTEGER, DIMENSION(:), ALLOCATABLE :: dum_cv !< dummy: connected_vertices
REAL(wp), DIMENSION(:), ALLOCATABLE :: dum_dtv !< dummy: distance_to_vertex
TYPE(mesh_point) :: in_mp !< Input mesh point
noc = in_mp%noc
ALLOCATE( dum_cv(1:noc),dum_dtv(1:noc) )
dum_cv = in_mp%connected_vertices(1:noc)
dum_dtv = in_mp%distance_to_vertex(1:noc)
DEALLOCATE( in_mp%connected_vertices, in_mp%distance_to_vertex )
ALLOCATE( in_mp%connected_vertices(1:noc), &
in_mp%distance_to_vertex(1:noc) )
in_mp%connected_vertices(1:noc) = dum_cv(1:noc)
in_mp%distance_to_vertex(1:noc) = dum_dtv(1:noc)
END SUBROUTINE reduce_connections
!------------------------------------------------------------------------------!
! Description:
! ------------
!> Writes all NavMesh information into binary file and building data to ASCII
!------------------------------------------------------------------------------!
SUBROUTINE bin_out_mesh
IMPLICIT NONE
INTEGER(iwp) :: il !< local counter
INTEGER(iwp) :: jl !< local counter
INTEGER(iwp) :: size_of_mesh !< size of mesh
INTEGER(iwp) :: size_of_pols !< size of polygon
WRITE(*,'(X,A)') 'Writing binary output data ...'
OPEN ( 14, FILE= TRIM(runname)//'_nav', FORM='UNFORMATTED', STATUS='replace' )
!
!-- Output of mesh data
size_of_mesh = SIZE(mesh)
WRITE(14) size_of_mesh
DO il = 1, size_of_mesh
WRITE(14) mesh(il)%polygon_id, mesh(il)%vertex_id, mesh(il)%noc, &
mesh(il)%origin_id, mesh(il)%cost_so_far, mesh(il)%x, &
mesh(il)%y, mesh(il)%x_s, mesh(il)%y_s
DO jl = 1, mesh(il)%noc
WRITE(14) mesh(il)%connected_vertices(jl), &
mesh(il)%distance_to_vertex(jl)
ENDDO
ENDDO
!
!-- Output of building polygon data
size_of_pols = SIZE(polygons)
WRITE(14) size_of_pols
DO il = 1, size_of_pols
WRITE(14) polygons(il)%nov
DO jl = 0, polygons(il)%nov+1
WRITE(14) polygons(il)%vertices(jl)%delete, &
polygons(il)%vertices(jl)%x, polygons(il)%vertices(jl)%y
ENDDO
ENDDO
CLOSE(14)
!
!-- Output building data to ASCII file
OPEN(UNIT=7,FILE='topo.txt',STATUS='replace',ACTION='write')
DO i = 1, polygon_counter
IF (polygons(i)%nov == 0) CYCLE
DO j = 1, polygons(i)%nov
WRITE(7,150) i,j,polygons(i)%vertices(j)%x, &
polygons(i)%vertices(j)%y
ENDDO
ENDDO
CLOSE(7)
WRITE(*,'(6X,A)') 'Done, tool terminating.', ' ', &
'Before starting your PALM run, please check the', &
'ASCII file topo.txt to see if you are satisfied', &
'with the polygon representation of the building', &
'data. If not, consider adjusting the parameter', &
'tolerance_dp accordingly.', ' ', 'Bye, Bye!', ' '
CALL CPU_TIME(finish)
WRITE(*,'(X,A,F10.4,A)') 'Total runtime: ', finish-start, ' seconds'
150 FORMAT (2(I7,X),2(F9.2,X) )
END SUBROUTINE bin_out_mesh
END MODULE mesh_creation
PROGRAM nav_mesh
USE mesh_creation
USE polygon_creation
USE variables
IMPLICIT NONE
!
!-- Start CPU mesurement
CALL CPU_TIME(start)
!
!-- Initialization
CALL init
WRITE(*,*) "Converting building data to polygons ..."
!
!-- Convert gridded building data to polygons
CALL identify_polygons
!
!-- Find corners in topography and add them to polygons
CALL identify_corners
!
!-- Sort polygons counter-clockwise, then simplify them
DO i = 1, polygon_counter
polygon => polygons(i)
nov = polygons(i)%nov
CALL sort_polygon(i)
!
!-- Simplify each polygon using douglas-peucker algorithm. If the number
!-- of vertices would fall below 4 due to this procedure, the tolerance
!-- for the algorithm is reduced and it is run again.
DO i_sc = 0, 2
CALL simplify_polygon(1,nov+1,tolerance_dp(i_sc))
i_cn = 0
DO j = 1, nov
IF ( .NOT. polygon%vertices(j)%delete ) i_cn = i_cn + 1
ENDDO
IF ( i_cn > 3 ) THEN
EXIT
ELSE
polygon%vertices(:)%delete = .FALSE.
ENDIF
ENDDO
CALL delete_extra_vertices(i)
ENDDO
!
!-- Remove buildings that are surrounded by another building
IF ( .NOT. internal_buildings ) THEN
DO i = 1, polygon_counter
polygon => polygons(i)
nov = polygons(i)%nov
CALL inside_other_polygon(i)
ENDDO
ENDIF
!
!-- Delete vertices that are marked for deletion
DO i = 1, polygon_counter
polygon => polygons(i)
nov = polygons(i)%nov
CALL delete_extra_vertices(i)
ENDDO
!
!-- Count number of vertices
vertex_counter = 0
DO i = 1, polygon_counter
polygon => polygons(i)
nov = polygons(i)%nov
vertex_counter = vertex_counter + nov
ENDDO
!
!-- Delete polygons with no vertices
CALL delete_empty_polygons
WRITE(*,'(2(6X,A,I10,X,A,/))') &
'Done. Created a total of', polygon_counter, 'polygon(s)', &
' with a total of', vertex_counter, 'vertices'
!
!-- Crate Navigation mesh from polygon data
CALL create_nav_mesh
!
!-- Binary mesh output
CALL bin_out_mesh
END PROGRAM nav_mesh