/usr/share/doc/libplplot12/examples/f95/x19f.f90 is in libplplot-dev 5.10.0+dfsg2-0.1ubuntu2.
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!
! Copyright (C) 2004 Alan W. Irwin
!
! This file is part of PLplot.
!
! PLplot is free software; you can redistribute it and/or modify
! it under the terms of the GNU Library General Public License as
! published by the Free Software Foundation; either version 2 of the
! License, or (at your option) any later version.
!
! PLplot 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 Library General Public License for more details.
!
! You should have received a copy of the GNU Library General Public
! License along with PLplot; if not, write to the Free Software
! Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA
subroutine map_transform(x, y, xt, yt)
use plplot, PI => PL_PI
implicit none
real(kind=plflt) x, y, xt, yt, radius
radius = 90.0_plflt - y
xt = radius * cos(x * PI / 180.0_plflt)
yt = radius * sin(x * PI / 180.0_plflt)
return
end subroutine
!--------------------------------------------------------------------------
! mapform19
!
! Defines specific coordinate transformation for example 19.
! Not to be confused with mapform in src/plmap.c.
! x(), y() are the coordinates to be plotted.
!--------------------------------------------------------------------------
subroutine mapform19(n, x, y)
use plplot, PI => PL_PI
implicit none
integer n
real(kind=plflt) x(n)
real(kind=plflt) y(n)
integer i
real(kind=plflt) xp, yp, radius
do i = 1,n
radius = 90.0_plflt - y(i)
xp = radius * cos(x(i) * PI / 180.0_plflt)
yp = radius * sin(x(i) * PI / 180.0_plflt)
x(i) = xp
y(i) = yp
enddo
return
end subroutine
! "Normalize" longitude values so that they always fall between
! -180.0 and 180.0
function normalize_longitude(lon)
use plplot
implicit none
real(kind=plflt) :: normalize_longitude
real(kind=plflt) :: lon, times
if ((lon .ge. -180.0_plflt) .and. (lon .le. 180.0_plflt)) then
normalize_longitude = lon
else
times = floor ((abs(lon) + 180.0_plflt) / 360.0_plflt)
if (lon .lt. 0.0_plflt) then
normalize_longitude = lon + 360.0_plflt * times
else
normalize_longitude = lon - 360.0_plflt * times
endif
endif
return
end function
!
! A custom axis labeling function for longitudes and latitudes.
!
subroutine geolocation_labeler(axis, value, label, length)
use plplot
implicit none
integer :: axis, length
real(kind=plflt) :: value
character(len=length) label
character(len=5) direction_label
real(kind=plflt) :: label_val = 0.0_plflt
real(kind=plflt) :: normalize_longitude
if (axis .eq. 2) then
label_val = value
if (label_val .gt. 0.0_plflt) then
direction_label = ' N'
else if (label_val .lt. 0.0_plflt) then
direction_label = ' S'
else
direction_label = 'Eq'
endif
else if (axis .eq. 1) then
label_val = normalize_longitude(value)
if (label_val .gt. 0.0_plflt) then
direction_label = ' E'
else if (label_val .lt. 0.0_plflt) then
direction_label = ' W'
else
direction_label = ''
endif
endif
if (axis .eq. 2 .and. value .eq. 0.0_plflt) then
! A special case for the equator
label = direction_label
else if (abs(label_val) .lt. 10.0_plflt) then
write(label,'(I1.1,A2)') iabs(int(label_val)),direction_label
else if (abs(label_val) .lt. 100.0_plflt) then
write(label,'(I2.1,A2)') iabs(int(label_val)),direction_label
else
write(label,'(I3.1,A2)') iabs(int(label_val)),direction_label
endif
end subroutine
!--------------------------------------------------------------------------
! main
!
! Shows two views of the world map.
!--------------------------------------------------------------------------
program x19f
use plplot
implicit none
real(kind=plflt) minx, maxx, miny, maxy
real(kind=plflt), dimension(1:1) :: x, y
external map_transform
external mapform19
external geolocation_labeler
! Process command-line arguments
call plparseopts(PL_PARSE_FULL)
! Longitude (x) and latitude (y)
miny = -70._plflt
maxy = 80._plflt
call plinit()
! Cartesian plots
! Most of world
minx = -170._plflt
maxx = minx+360._plflt
! Setup a custom latitude and longitude-based scaling function.
call plslabelfunc(geolocation_labeler)
call plcol0(1)
call plenv(minx, maxx, miny, maxy, 1, 70)
call plmap('usaglobe', minx, maxx, miny, maxy)
! The Americas
minx = 190._plflt
maxx = 340._plflt
call plcol0(1)
call plenv(minx, maxx, miny, maxy, 1, 70)
call plmap('usaglobe', minx, maxx, miny, maxy)
! Clear the labeling function
call plslabelfunc(0)
! Polar, Northern hemisphere
minx = 0._plflt
maxx = 360._plflt
call plenv(-75._plflt, 75._plflt, -75._plflt, &
75._plflt, 1, -1)
call plmap(mapform19,'globe', minx, maxx, miny, maxy)
call pllsty(2)
call plmeridians(mapform19,10.0_plflt, 10.0_plflt, &
0.0_plflt, 360.0_plflt, -10.0_plflt, &
80.0_plflt)
! Polar, Northern hemisphere, this time with a PLplot-wide transform
minx = 0._plflt
maxx = 360._plflt
call plstransform( map_transform )
call pllsty( 1 )
call plenv( -75._plflt, 75._plflt, -75._plflt, &
75._plflt, 1, -1 )
! No need to set the map transform here as the global
! transform will be used.
call plmap('globe', minx, maxx, miny, maxy )
call pllsty( 2 )
call plmeridians(10.0_plflt, 10.0_plflt, &
0.0_plflt, 360.0_plflt, -10.0_plflt, &
80.0_plflt )
! Show Baltimore, MD on the map
call plcol0( 2 )
call plssym( 0.0_plflt, 2.0_plflt )
x=-76.6125_plflt
y=39.2902778_plflt
call plpoin( x, y, 18 )
call plssym( 0.0_plflt, 1.0_plflt )
call plptex( -76.6125_plflt, 43.0_plflt, 0.0_plflt, &
0.0_plflt, 0.0_plflt, 'Baltimore, MD' )
! For f95, this is how the global transform is cleared
call plstransform( 0 )
call plend()
end program x19f
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