!-------------------------------------------------------------------------------
!
! This file is part of the WSPR application, Weak Signal Propagation Reporter
!
! File Name: wspr_old_subs.f90
! Description: Utility subroutines from WSPR 2.0
!
! Copyright (C) 2001-2014 Joseph Taylor, K1JT
! License: GPL-3
!
! This program 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.
!
! This program 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
! this program; if not, write to the Free Software Foundation, Inc., 51 Franklin
! Street, Fifth Floor, Boston, MA 02110-1301, USA.
!
!-------------------------------------------------------------------------------
subroutine deg2grid(dlong0,dlat,grid)
real dlong !West longitude (deg)
real dlat !Latitude (deg)
character grid*6
dlong=dlong0
if(dlong.lt.-180.0) dlong=dlong+360.0
if(dlong.gt.180.0) dlong=dlong-360.0
! Convert to units of 5 min of longitude, working east from 180 deg.
nlong=60.0*(180.0-dlong)/5.0
n1=nlong/240 !20-degree field
n2=(nlong-240*n1)/24 !2 degree square
n3=nlong-240*n1-24*n2 !5 minute subsquare
grid(1:1)=char(ichar('A')+n1)
grid(3:3)=char(ichar('0')+n2)
grid(5:5)=char(ichar('a')+n3)
! Convert to units of 2.5 min of latitude, working north from -90 deg.
nlat=60.0*(dlat+90)/2.5
n1=nlat/240 !10-degree field
n2=(nlat-240*n1)/24 !1 degree square
n3=nlat-240*n1-24*n2 !2.5 minuts subsquare
grid(2:2)=char(ichar('A')+n1)
grid(4:4)=char(ichar('0')+n2)
grid(6:6)=char(ichar('a')+n3)
return
end subroutine deg2grid
subroutine encode232(dat,nbytes,symbol,maxsym)
! Convolutional encoder for a K=32, r=1/2 code.
integer*1 dat(nbytes) !User data, packed 8 bits per byte
integer*1 symbol(maxsym) !Channel symbols, one bit per byte
integer*1 i1
! Layland-Lushbaugh polynomials for a K=32, r=1/2 convolutional code,
! and 8-bit parity lookup table.
data npoly1/-221228207/,npoly2/-463389625/
integer*1 partab(0:255)
data partab/ &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0/
nstate=0
k=0
do j=1,nbytes
do i=7,0,-1
i1=dat(j)
i4=i1
if (i4.lt.0) i4=i4+256
nstate=ior(ishft(nstate,1),iand(ishft(i4,-i),1))
n=iand(nstate,npoly1)
n=ieor(n,ishft(n,-16))
k=k+1
symbol(k)=partab(iand(ieor(n,ishft(n,-8)),255))
n=iand(nstate,npoly2)
n=ieor(n,ishft(n,-16))
k=k+1
symbol(k)=partab(iand(ieor(n,ishft(n,-8)),255))
enddo
enddo
return
end subroutine encode232
subroutine fano232(symbol,nbits,mettab,ndelta,maxcycles,dat,ncycles,metric,ierr)
! Sequential decoder for K=32, r=1/2 convolutional code using
! the Fano algorithm. Translated from C routine for same purpose
! written by Phil Karn, KA9Q.
parameter (MAXBITS=103)
parameter (MAXDAT=(MAXBITS+7)/8)
integer*1 symbol(0:2*MAXBITS-1)
integer*1 dat(MAXDAT) !Decoded user data, 8 bits per byte
integer mettab(0:255,0:1) !Metric table
! These were the "node" structure in Karn's C code:
integer nstate(0:MAXBITS-1) !Encoder state of next node
integer gamma(0:MAXBITS-1) !Cumulative metric to this node
integer metrics(0:3,0:MAXBITS-1) !Metrics indexed by all possible Tx syms
integer tm(0:1,0:MAXBITS-1) !Sorted metrics for current hypotheses
integer ii(0:MAXBITS-1) !Current branch being tested
logical noback
! Layland-Lushbaugh polynomials for a K=32, r=1/2 convolutional code,
! and 8-bit parity lookup table.
data npoly1/-221228207/,npoly2/-463389625/
integer*1 partab(0:255)
data partab/ &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0, &
0, 1, 1, 0, 1, 0, 0, 1, &
0, 1, 1, 0, 1, 0, 0, 1, &
1, 0, 0, 1, 0, 1, 1, 0/
ntail=nbits-31
! Compute all possible branch metrics for each symbol pair.
! This is the only place we actually look at the raw input symbols
i4a=0
i4b=0
do np=0,nbits-1
j=2*np
i4a=symbol(j)
i4b=symbol(j+1)
if (i4a.lt.0) i4a=i4a+256
if (i4b.lt.0) i4b=i4b+256
metrics(0,np) = mettab(i4a,0) + mettab(i4b,0)
metrics(1,np) = mettab(i4a,0) + mettab(i4b,1)
metrics(2,np) = mettab(i4a,1) + mettab(i4b,0)
metrics(3,np) = mettab(i4a,1) + mettab(i4b,1)
enddo
np=0
nstate(np)=0
! Compute and sort branch metrics from the root node
n=iand(nstate(np),npoly1)
n=ieor(n,ishft(n,-16))
lsym=partab(iand(ieor(n,ishft(n,-8)),255))
n=iand(nstate(np),npoly2)
n=ieor(n,ishft(n,-16))
lsym=lsym+lsym+partab(iand(ieor(n,ishft(n,-8)),255))
m0=metrics(lsym,np)
m1=metrics(ieor(3,lsym),np)
if(m0.gt.m1) then
tm(0,np)=m0 !0-branch has better metric
tm(1,np)=m1
else
tm(0,np)=m1 !1-branch is better
tm(1,np)=m0
nstate(np)=nstate(np) + 1 !Set low bit
endif
! Start with best branch
ii(np)=0
gamma(np)=0
nt=0
! Start the Fano decoder
do i=1,nbits*maxcycles
! Look forward
ngamma=gamma(np) + tm(ii(np),np)
if(ngamma.ge.nt) then
! Node is acceptable. If first time visiting this node, tighten threshold:
if(gamma(np).lt.(nt+ndelta)) nt=nt + &
ndelta * ((ngamma-nt)/ndelta)
! Move forward
gamma(np+1)=ngamma
nstate(np+1)=ishft(nstate(np),1)
np=np+1
if(np.eq.nbits-1) go to 100 !We're done!
n=iand(nstate(np),npoly1)
n=ieor(n,ishft(n,-16))
lsym=partab(iand(ieor(n,ishft(n,-8)),255))
n=iand(nstate(np),npoly2)
n=ieor(n,ishft(n,-16))
lsym=lsym+lsym+partab(iand(ieor(n,ishft(n,-8)),255))
if(np.ge.ntail) then
tm(0,np)=metrics(lsym,np) !We're in the tail, all zeros
else
m0=metrics(lsym,np)
m1=metrics(ieor(3,lsym),np)
if(m0.gt.m1) then
tm(0,np)=m0 !0-branch has better metric
tm(1,np)=m1
else
tm(0,np)=m1 !1-branch is better
tm(1,np)=m0
nstate(np)=nstate(np) + 1 !Set low bit
endif
endif
ii(np)=0 !Start with best branch
go to 99
endif
! Threshold violated, can't go forward
10 noback=.false.
if(np.eq.0) noback=.true.
if(np.gt.0) then
if(gamma(np-1).lt.nt) noback=.true.
endif
if(noback) then
! Can't back up, either. Relax threshold and look forward again
! to a better branch.
nt=nt-ndelta
if(ii(np).ne.0) then
ii(np)=0
nstate(np)=ieor(nstate(np),1)
endif
go to 99
endif
! Back up
np=np-1
if(np.lt.ntail .and. ii(np).ne.1) then
! Search the next best branch
ii(np)=ii(np)+1
nstate(np)=ieor(nstate(np),1)
go to 99
endif
go to 10
99 continue
enddo
i=nbits*maxcycles
100 metric=gamma(np) !Final path metric
! Copy decoded data to user's buffer
nbytes=(nbits+7)/8
np=7
do j=1,nbytes-1
i4a=nstate(np)
dat(j)=i4a
np=np+8
enddo
dat(nbytes)=0
ncycles=i+1
ierr=0
if(i.ge.maxcycles*nbits) ierr=-1
return
end subroutine fano232
subroutine grid2deg(grid0,dlong,dlat)
! Converts Maidenhead grid locator to degrees of West longitude
! and North latitude.
character*6 grid0,grid
character*1 g1,g2,g3,g4,g5,g6
grid=grid0
i=ichar(grid(5:5))
if(grid(5:5).eq.' ' .or. i.le.64 .or. i.ge.128) grid(5:6)='mm'
if(grid(1:1).ge.'a' .and. grid(1:1).le.'z') grid(1:1)= &
char(ichar(grid(1:1))+ichar('A')-ichar('a'))
if(grid(2:2).ge.'a' .and. grid(2:2).le.'z') grid(2:2)= &
char(ichar(grid(2:2))+ichar('A')-ichar('a'))
if(grid(5:5).ge.'A' .and. grid(5:5).le.'Z') grid(5:5)= &
char(ichar(grid(5:5))-ichar('A')+ichar('a'))
if(grid(6:6).ge.'A' .and. grid(6:6).le.'Z') grid(6:6)= &
char(ichar(grid(6:6))-ichar('A')+ichar('a'))
g1=grid(1:1)
g2=grid(2:2)
g3=grid(3:3)
g4=grid(4:4)
g5=grid(5:5)
g6=grid(6:6)
nlong = 180 - 20*(ichar(g1)-ichar('A'))
n20d = 2*(ichar(g3)-ichar('0'))
xminlong = 5*(ichar(g5)-ichar('a')+0.5)
dlong = nlong - n20d - xminlong/60.0
nlat = -90+10*(ichar(g2)-ichar('A')) + ichar(g4)-ichar('0')
xminlat = 2.5*(ichar(g6)-ichar('a')+0.5)
dlat = nlat + xminlat/60.0
return
end subroutine grid2deg
subroutine hash(string,len,ihash)
parameter (MASK15=32767)
character*(*) string
integer*1 ic(12)
do i=1,len
ic(i)=ichar(string(i:i))
enddo
i=nhash(ic,len,146)
ihash=iand(i,MASK15)
! print*,'C',ihash,len,string
return
end subroutine hash
subroutine inter_mept(id,ndir)
! Interleave (ndir=1) or de-interleave (ndir=-1) the array id.
integer*1 id(0:161),itmp(0:161)
integer j0(0:161)
logical first
data first/.true./
save
if(first) then
! Compute the interleave table using bit reversal.
k=-1
do i=0,255
n=0
ii=i
do j=0,7
n=n+n
if(iand(ii,1).ne.0) n=n+1
ii=ii/2
enddo
if(n.le.161) then
k=k+1
j0(k)=n
endif
enddo
first=.false.
endif
if(ndir.eq.1) then
do i=0,161
itmp(j0(i))=id(i)
enddo
else
do i=0,161
itmp(i)=id(j0(i))
enddo
endif
do i=0,161
id(i)=itmp(i)
enddo
return
end subroutine inter_mept
function nchar(c)
! Convert ASCII number, letter, or space to 0-36 for callsign packing.
character c*1
data n/0/ !Silence compiler warning
if(c.ge.'0' .and. c.le.'9') then
n=ichar(c)-ichar('0')
else if(c.ge.'A' .and. c.le.'Z') then
n=ichar(c)-ichar('A') + 10
else if(c.ge.'a' .and. c.le.'z') then
n=ichar(c)-ichar('a') + 10
else if(c.ge.' ') then
n=36
else
Print*,'Invalid character in callsign ',c,' ',ichar(c)
stop
endif
nchar=n
return
end function nchar
subroutine pack50(n1,n2,dat)
integer*1 dat(11),i1
i1=iand(ishft(n1,-20),255) !8 bits
dat(1)=i1
i1=iand(ishft(n1,-12),255) !8 bits
dat(2)=i1
i1=iand(ishft(n1, -4),255) !8 bits
dat(3)=i1
i1=16*iand(n1,15)+iand(ishft(n2,-18),15) !4+4 bits
dat(4)=i1
i1=iand(ishft(n2,-10),255) !8 bits
dat(5)=i1
i1=iand(ishft(n2, -2),255) !8 bits
dat(6)=i1
i1=64*iand(n2,3) !2 bits
dat(7)=i1
dat(8)=0
dat(9)=0
dat(10)=0
dat(11)=0
return
end subroutine pack50
subroutine packcall(callsign,ncall,text)
! Pack a valid callsign into a 28-bit integer.
parameter (NBASE=37*36*10*27*27*27)
character callsign*6,c*1,tmp*6,digit*10
logical text
data digit/'0123456789'/
text=.false.
! Work-around for Swaziland prefix:
if(callsign(1:4).eq.'3DA0') callsign='3D0'//callsign(5:6)
if(callsign(1:3).eq.'CQ ') then
ncall=NBASE + 1
if(callsign(4:4).ge.'0' .and. callsign(4:4).le.'9' .and. &
callsign(5:5).ge.'0' .and. callsign(5:5).le.'9' .and. &
callsign(6:6).ge.'0' .and. callsign(6:6).le.'9') then
nfreq=100*(ichar(callsign(4:4))-48) + &
10*(ichar(callsign(5:5))-48) + &
ichar(callsign(6:6))-48
ncall=NBASE + 3 + nfreq
endif
return
else if(callsign(1:4).eq.'QRZ ') then
ncall=NBASE + 2
return
endif
tmp=' '
if(callsign(3:3).ge.'0' .and. callsign(3:3).le.'9') then
tmp=callsign
else if(callsign(2:2).ge.'0' .and. callsign(2:2).le.'9') then
if(callsign(6:6).ne.' ') then
text=.true.
return
endif
tmp=' '//callsign
else
text=.true.
return
endif
do i=1,6
c=tmp(i:i)
if(c.ge.'a' .and. c.le.'z') &
tmp(i:i)=char(ichar(c)-ichar('a')+ichar('A'))
enddo
n1=0
if((tmp(1:1).ge.'A'.and.tmp(1:1).le.'Z').or.tmp(1:1).eq.' ') n1=1
if(tmp(1:1).ge.'0' .and. tmp(1:1).le.'9') n1=1
n2=0
if(tmp(2:2).ge.'A' .and. tmp(2:2).le.'Z') n2=1
if(tmp(2:2).ge.'0' .and. tmp(2:2).le.'9') n2=1
n3=0
if(tmp(3:3).ge.'0' .and. tmp(3:3).le.'9') n3=1
n4=0
if((tmp(4:4).ge.'A'.and.tmp(4:4).le.'Z').or.tmp(4:4).eq.' ') n4=1
n5=0
if((tmp(5:5).ge.'A'.and.tmp(5:5).le.'Z').or.tmp(5:5).eq.' ') n5=1
n6=0
if((tmp(6:6).ge.'A'.and.tmp(6:6).le.'Z').or.tmp(6:6).eq.' ') n6=1
if(n1+n2+n3+n4+n5+n6 .ne. 6) then
text=.true.
return
endif
ncall=nchar(tmp(1:1))
ncall=36*ncall+nchar(tmp(2:2))
ncall=10*ncall+nchar(tmp(3:3))
ncall=27*ncall+nchar(tmp(4:4))-10
ncall=27*ncall+nchar(tmp(5:5))-10
ncall=27*ncall+nchar(tmp(6:6))-10
return
end subroutine packcall
subroutine packgrid(grid,ng,text)
parameter (NGBASE=180*180)
character*4 grid
logical text
text=.false.
if(grid.eq.' ') go to 90 !Blank grid is OK
! Test for numerical signal report, etc.
if(grid(1:1).eq.'-') then
n=10*(ichar(grid(2:2))-48) + ichar(grid(3:3)) - 48
ng=NGBASE+1+n
go to 100
else if(grid(1:2).eq.'R-') then
n=10*(ichar(grid(3:3))-48) + ichar(grid(4:4)) - 48
if(n.eq.0) go to 90
ng=NGBASE+31+n
go to 100
else if(grid(1:2).eq.'RO') then
ng=NGBASE+62
go to 100
else if(grid(1:3).eq.'RRR') then
ng=NGBASE+63
go to 100
else if(grid(1:2).eq.'73') then
ng=NGBASE+64
go to 100
endif
if(grid(1:1).lt.'A' .or. grid(1:1).gt.'R') text=.true.
if(grid(2:2).lt.'A' .or. grid(2:2).gt.'R') text=.true.
if(grid(3:3).lt.'0' .or. grid(3:3).gt.'9') text=.true.
if(grid(4:4).lt.'0' .or. grid(4:4).gt.'9') text=.true.
if(text) go to 100
call grid2deg(grid//'mm',dlong,dlat)
long=dlong
lat=dlat+ 90.0
ng=((long+180)/2)*180 + lat
go to 100
90 ng=NGBASE + 1
100 return
end subroutine packgrid
subroutine packpfx(call1,n1,ng,nadd)
character*12 call1,call0
character*3 pfx
logical text
i1=index(call1,'/')
if(call1(i1+2:i1+2).eq.' ') then
! Single-character add-on suffix (maybe also fourth suffix letter?)
call0=call1(:i1-1)
call packcall(call0,n1,text)
nadd=1
nc=ichar(call1(i1+1:i1+1))
if(nc.ge.48 .and. nc.le.57) then
n=nc-48
else if(nc.ge.65 .and. nc.le.90) then
n=nc-65+10
else
n=38
endif
nadd=1
ng=60000-32768+n
else if(call1(i1+3:i1+3).eq.' ') then
! Two-character numerical suffix, /10 to /99
call0=call1(:i1-1)
call packcall(call0,n1,text)
nadd=1
n=10*(ichar(call1(i1+1:i1+1))-48) + ichar(call1(i1+2:i1+2)) - 48
nadd=1
ng=60000 + 26 + n
else
! Prefix of 1 to 3 characters
pfx=call1(:i1-1)
if(pfx(3:3).eq.' ') pfx=' '//pfx
if(pfx(3:3).eq.' ') pfx=' '//pfx
call0=call1(i1+1:)
call packcall(call0,n1,text)
ng=0
do i=1,3
nc=ichar(pfx(i:i))
if(nc.ge.48 .and. nc.le.57) then
n=nc-48
else if(nc.ge.65 .and. nc.le.90) then
n=nc-65+10
else
n=36
endif
ng=37*ng + n
enddo
nadd=0
if(ng.ge.32768) then
ng=ng-32768
nadd=1
endif
endif
return
end subroutine packpfx
subroutine unpack50(dat,n1,n2)
integer*1 dat(11)
i=dat(1)
i4=iand(i,255)
n1=ishft(i4,20)
i=dat(2)
i4=iand(i,255)
n1=n1 + ishft(i4,12)
i=dat(3)
i4=iand(i,255)
n1=n1 + ishft(i4,4)
i=dat(4)
i4=iand(i,255)
n1=n1 + iand(ishft(i4,-4),15)
n2=ishft(iand(i4,15),18)
i=dat(5)
i4=iand(i,255)
n2=n2 + ishft(i4,10)
i=dat(6)
i4=iand(i,255)
n2=n2 + ishft(i4,2)
i=dat(7)
i4=iand(i,255)
n2=n2 + iand(ishft(i4,-6),3)
return
end subroutine unpack50
subroutine unpackcall(ncall,word)
character word*12,c*37
data c/'0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ '/
n=ncall
word='......'
if(n.ge.262177560) go to 999 !Plain text message ...
i=mod(n,27)+11
word(6:6)=c(i:i)
n=n/27
i=mod(n,27)+11
word(5:5)=c(i:i)
n=n/27
i=mod(n,27)+11
word(4:4)=c(i:i)
n=n/27
i=mod(n,10)+1
word(3:3)=c(i:i)
n=n/10
i=mod(n,36)+1
word(2:2)=c(i:i)
n=n/36
i=n+1
word(1:1)=c(i:i)
do i=1,4
if(word(i:i).ne.' ') go to 10
enddo
go to 999
10 word=word(i:)
999 if(word(1:3).eq.'3D0') word='3DA0'//word(4:)
return
end subroutine unpackcall
subroutine unpackgrid(ng,grid)
parameter (NGBASE=180*180)
character grid*4,grid6*6,digit*10
data digit/'0123456789'/
grid=' '
if(ng.ge.32400) go to 10
dlat=mod(ng,180)-90
dlong=(ng/180)*2 - 180 + 2
call deg2grid(dlong,dlat,grid6)
grid=grid6(1:4) !XXX explicitly truncate this -db
go to 100
10 n=ng-NGBASE-1
if(n.ge.1 .and.n.le.30) then
grid(1:1)='-'
grid(2:2)=char(48+n/10)
grid(3:3)=char(48+mod(n,10))
else if(n.ge.31 .and.n.le.60) then
n=n-30
grid(1:2)='R-'
grid(3:3)=char(48+n/10)
grid(4:4)=char(48+mod(n,10))
else if(n.eq.61) then
grid='RO'
else if(n.eq.62) then
grid='RRR'
else if(n.eq.63) then
grid='73'
endif
100 return
end subroutine unpackgrid
subroutine unpackpfx(ng,call1)
character*12 call1
character*3 pfx
if(ng.lt.60000) then
! Add-on prefix of 1 to 3 characters
n=ng
do i=3,1,-1
nc=mod(n,37)
if(nc.ge.0 .and. nc.le.9) then
pfx(i:i)=char(nc+48)
else if(nc.ge.10 .and. nc.le.35) then
pfx(i:i)=char(nc+55)
else
pfx(i:i)=' '
endif
n=n/37
enddo
call1=pfx//'/'//call1
if(call1(1:1).eq.' ') call1=call1(2:)
if(call1(1:1).eq.' ') call1=call1(2:)
else
! Add-on suffix, one or teo characters
i1=index(call1,' ')
nc=ng-60000
if(nc.ge.0 .and. nc.le.9) then
call1=call1(:i1-1)//'/'//char(nc+48)
else if(nc.ge.10 .and. nc.le.35) then
call1=call1(:i1-1)//'/'//char(nc+55)
else if(nc.ge.36 .and. nc.le.125) then
nc1=(nc-26)/10
nc2=mod(nc-26,10)
call1=call1(:i1-1)//'/'//char(nc1+48)//char(nc2+48)
endif
endif
return
end subroutine unpackpfx
subroutine wqdecode(data0,message,ntype)
parameter (N15=32768)
integer*1 data0(11)
character*22 message
character*12 callsign
character*3 cdbm
character grid4*4,grid6*6
logical first
character*12 dcall(0:N15-1)
data first/.true./
save first,dcall
! May want to have a timeout (say, one hour?) on calls fetched
! from the hash table.
if(first) then
dcall=' '
first=.false.
endif
message=' '
call unpack50(data0,n1,n2)
call unpackcall(n1,callsign)
i1=index(callsign,' ')
call unpackgrid(n2/128,grid4)
ntype=iand(n2,127) -64
! Standard WSPR message (types 0 3 7 10 13 17 ... 60)
if(ntype.ge.0 .and. ntype.le.62) then
nu=mod(ntype,10)
if(nu.eq.0 .or. nu.eq.3 .or. nu.eq.7) then
write(cdbm,'(i3)'),ntype
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
message=callsign(1:i1)//grid4//' '//cdbm
call hash(callsign,i1-1,ih)
dcall(ih)=callsign(:i1)
else
nadd=nu
if(nu.gt.3) nadd=nu-3
if(nu.gt.7) nadd=nu-7
ng=n2/128 + 32768*(nadd-1)
call unpackpfx(ng,callsign)
ndbm=ntype-nadd
write(cdbm,'(i3)'),ndbm
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
i2=index(callsign,' ')
message=callsign(:i2)//cdbm
call hash(callsign,i2-1,ih)
dcall(ih)=callsign(:i2)
endif
else if(ntype.lt.0) then
ndbm=-(ntype+1)
grid6=callsign(6:6)//callsign(1:5)
ih=(n2-ntype-64)/128
callsign=dcall(ih)
write(cdbm,'(i3)'),ndbm
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
if(cdbm(1:1).eq.' ') cdbm=cdbm(2:)
i2=index(callsign,' ')
if(dcall(ih)(1:1).ne.' ') then
message='<'//callsign(:i2-1)//'> '//grid6//' '//cdbm
else
message='<...> '//grid6//' '//cdbm
endif
endif
return
end subroutine wqdecode
subroutine wqencode(msg,ntype,data0)
! Parse and encode a WSPR message.
parameter (MASK15=32767)
character*22 msg
character*12 call1,call2
character grid4*4,grid6*6
logical lbad1,lbad2
integer*1 data0(11)
integer nu(0:9)
data nu/0,-1,1,0,-1,2,1,0,-1,1/
! Standard WSPR message (types 0 3 7 10 13 17 ... 60)
i1=index(msg,' ')
i2=index(msg,'/')
i3=index(msg,'<')
call1=msg(:i1-1)
if(i1.lt.3 .or. i1.gt.7 .or. i2.gt.0 .or. i3.gt.0) go to 10
grid4=msg(i1+1:i1+4)
call packcall(call1,n1,lbad1)
call packgrid(grid4,ng,lbad2)
if(lbad1 .or. lbad2) go to 10
ndbm=0
read(msg(i1+5:),*) ndbm
if(ndbm.lt.0) ndbm=0
if(ndbm.gt.60) ndbm=60
ndbm=ndbm+nu(mod(ndbm,10))
n2=128*ng + (ndbm+64)
call pack50(n1,n2,data0)
ntype=ndbm
go to 900
10 if(i2.ge.2 .and. i3.lt.1) then
call packpfx(call1,n1,ng,nadd)
ndbm=0
read(msg(i1+1:),*) ndbm
if(ndbm.lt.0) ndbm=0
if(ndbm.gt.60) ndbm=60
ndbm=ndbm+nu(mod(ndbm,10))
ntype=ndbm + 1 + nadd
n2=128*ng + ntype + 64
call pack50(n1,n2,data0)
else if(i3.eq.1) then
i4=index(msg,'>')
call1=msg(2:i4-1)
call hash(call1,i4-2,ih)
grid6=msg(i1+1:i1+6)
call2=grid6(2:6)//grid6(1:1)//' '
call packcall(call2,n1,lbad1)
ndbm=0
read(msg(i1+8:),*) ndbm
if(ndbm.lt.0) ndbm=0
if(ndbm.gt.60) ndbm=60
ndbm=ndbm+nu(mod(ndbm,10))
ntype=-(ndbm+1)
n2=128*ih + ntype + 64
call pack50(n1,n2,data0)
endif
go to 900
900 continue
return
end subroutine wqencode