subroutine r1fgkf ( ido, ip, l1, idl1, cc, c1, c2, in1, ch, ch2, in2, wa )
!*****************************************************************************80
!
!! R1FGKF is an FFTPACK5 auxiliary routine.
!
! License:
!
! Licensed under the GNU General Public License (GPL).
! Copyright (C) 1995-2004, Scientific Computing Division,
! University Corporation for Atmospheric Research
!
! Modified:
!
! 27 March 2009
!
! Author:
!
! Paul Swarztrauber
! Richard Valent
!
! Reference:
!
! Paul Swarztrauber,
! Vectorizing the Fast Fourier Transforms,
! in Parallel Computations,
! edited by G. Rodrigue,
! Academic Press, 1982.
!
! Paul Swarztrauber,
! Fast Fourier Transform Algorithms for Vector Computers,
! Parallel Computing, pages 45-63, 1984.
!
! Parameters:
!
implicit none
integer ( kind = 4 ) idl1
integer ( kind = 4 ) ido
integer ( kind = 4 ) in1
integer ( kind = 4 ) in2
integer ( kind = 4 ) ip
integer ( kind = 4 ) l1
real ( kind = 4 ) ai1
real ( kind = 4 ) ai2
real ( kind = 4 ) ar1
real ( kind = 4 ) ar1h
real ( kind = 4 ) ar2
real ( kind = 4 ) ar2h
real ( kind = 4 ) arg
real ( kind = 4 ) c1(in1,ido,l1,ip)
real ( kind = 4 ) c2(in1,idl1,ip)
real ( kind = 4 ) cc(in1,ido,ip,l1)
real ( kind = 4 ) ch(in2,ido,l1,ip)
real ( kind = 4 ) ch2(in2,idl1,ip)
real ( kind = 4 ) dc2
real ( kind = 4 ) dcp
real ( kind = 4 ) ds2
real ( kind = 4 ) dsp
integer ( kind = 4 ) i
integer ( kind = 4 ) ic
integer ( kind = 4 ) idij
integer ( kind = 4 ) idp2
integer ( kind = 4 ) ik
integer ( kind = 4 ) ipp2
integer ( kind = 4 ) ipph
integer ( kind = 4 ) is
integer ( kind = 4 ) j
integer ( kind = 4 ) j2
integer ( kind = 4 ) jc
integer ( kind = 4 ) k
integer ( kind = 4 ) l
integer ( kind = 4 ) lc
integer ( kind = 4 ) nbd
real ( kind = 4 ) tpi
real ( kind = 4 ) wa(ido)
tpi = 2.0E+00 * 4.0E+00 * atan ( 1.0E+00 )
arg = tpi / real ( ip, kind = 4 )
dcp = cos ( arg )
dsp = sin ( arg )
ipph = ( ip + 1 ) / 2
ipp2 = ip + 2
idp2 = ido + 2
nbd = ( ido - 1 ) / 2
if ( ido == 1 ) then
do ik = 1, idl1
c2(1,ik,1) = ch2(1,ik,1)
end do
else
do ik = 1, idl1
ch2(1,ik,1) = c2(1,ik,1)
end do
do j = 2, ip
do k = 1, l1
ch(1,1,k,j) = c1(1,1,k,j)
end do
end do
if ( l1 < nbd ) then
is = -ido
do j = 2, ip
is = is + ido
do k = 1, l1
idij = is
do i = 3, ido, 2
idij = idij + 2
ch(1,i-1,k,j) = wa(idij-1)*c1(1,i-1,k,j)+wa(idij) *c1(1,i,k,j)
ch(1,i,k,j) = wa(idij-1)*c1(1,i,k,j)-wa(idij) *c1(1,i-1,k,j)
end do
end do
end do
else
is = -ido
do j = 2, ip
is = is + ido
idij = is
do i = 3, ido, 2
idij = idij + 2
do k = 1, l1
ch(1,i-1,k,j) = wa(idij-1)*c1(1,i-1,k,j)+wa(idij) *c1(1,i,k,j)
ch(1,i,k,j) = wa(idij-1)*c1(1,i,k,j)-wa(idij) *c1(1,i-1,k,j)
end do
end do
end do
end if
if ( nbd < l1 ) then
do j = 2, ipph
jc = ipp2 - j
do i = 3, ido, 2
do k = 1, l1
c1(1,i-1,k,j) = ch(1,i-1,k,j)+ch(1,i-1,k,jc)
c1(1,i-1,k,jc) = ch(1,i,k,j)-ch(1,i,k,jc)
c1(1,i,k,j) = ch(1,i,k,j)+ch(1,i,k,jc)
c1(1,i,k,jc) = ch(1,i-1,k,jc)-ch(1,i-1,k,j)
end do
end do
end do
else
do j = 2, ipph
jc = ipp2 - j
do k = 1, l1
do i = 3, ido, 2
c1(1,i-1,k,j) = ch(1,i-1,k,j)+ch(1,i-1,k,jc)
c1(1,i-1,k,jc) = ch(1,i,k,j)-ch(1,i,k,jc)
c1(1,i,k,j) = ch(1,i,k,j)+ch(1,i,k,jc)
c1(1,i,k,jc) = ch(1,i-1,k,jc)-ch(1,i-1,k,j)
end do
end do
end do
end if
end if
do j = 2, ipph
jc = ipp2 - j
do k = 1, l1
c1(1,1,k,j) = ch(1,1,k,j)+ch(1,1,k,jc)
c1(1,1,k,jc) = ch(1,1,k,jc)-ch(1,1,k,j)
end do
end do
ar1 = 1.0E+00
ai1 = 0.0E+00
do l = 2, ipph
lc = ipp2 - l
ar1h = dcp * ar1 - dsp * ai1
ai1 = dcp * ai1 + dsp * ar1
ar1 = ar1h
do ik = 1, idl1
ch2(1,ik,l) = c2(1,ik,1)+ar1*c2(1,ik,2)
ch2(1,ik,lc) = ai1*c2(1,ik,ip)
end do
dc2 = ar1
ds2 = ai1
ar2 = ar1
ai2 = ai1
do j = 3, ipph
jc = ipp2 - j
ar2h = dc2 * ar2 - ds2 * ai2
ai2 = dc2 * ai2 + ds2 * ar2
ar2 = ar2h
do ik = 1, idl1
ch2(1,ik,l) = ch2(1,ik,l)+ar2*c2(1,ik,j)
ch2(1,ik,lc) = ch2(1,ik,lc)+ai2*c2(1,ik,jc)
end do
end do
end do
do j = 2, ipph
do ik = 1, idl1
ch2(1,ik,1) = ch2(1,ik,1)+c2(1,ik,j)
end do
end do
if ( ido < l1 ) then
do i = 1, ido
do k = 1, l1
cc(1,i,1,k) = ch(1,i,k,1)
end do
end do
else
do k = 1, l1
do i = 1, ido
cc(1,i,1,k) = ch(1,i,k,1)
end do
end do
end if
do j = 2, ipph
jc = ipp2 - j
j2 = j+j
do k = 1, l1
cc(1,ido,j2-2,k) = ch(1,1,k,j)
cc(1,1,j2-1,k) = ch(1,1,k,jc)
end do
end do
if ( ido == 1 ) then
return
end if
if ( nbd < l1 ) then
do j = 2, ipph
jc = ipp2 - j
j2 = j + j
do i = 3, ido, 2
ic = idp2 - i
do k = 1, l1
cc(1,i-1,j2-1,k) = ch(1,i-1,k,j)+ch(1,i-1,k,jc)
cc(1,ic-1,j2-2,k) = ch(1,i-1,k,j)-ch(1,i-1,k,jc)
cc(1,i,j2-1,k) = ch(1,i,k,j)+ch(1,i,k,jc)
cc(1,ic,j2-2,k) = ch(1,i,k,jc)-ch(1,i,k,j)
end do
end do
end do
else
do j = 2, ipph
jc = ipp2 - j
j2 = j + j
do k = 1, l1
do i = 3, ido, 2
ic = idp2 - i
cc(1,i-1,j2-1,k) = ch(1,i-1,k,j) + ch(1,i-1,k,jc)
cc(1,ic-1,j2-2,k) = ch(1,i-1,k,j) - ch(1,i-1,k,jc)
cc(1,i,j2-1,k) = ch(1,i,k,j) + ch(1,i,k,jc)
cc(1,ic,j2-2,k) = ch(1,i,k,jc) - ch(1,i,k,j)
end do
end do
end do
end if
return
end