subroutine zmf3kf ( lot, ido, l1, na, cc, im1, in1, ch, im2, in2, wa )
!*****************************************************************************80
!
!! ZMF3KF is an FFTPACK5 auxiliary routine.
!
! License:
!
! Licensed under the GNU General Public License (GPL).
!
! Modified:
!
! 26 Ausust 2009
!
! Author:
!
! Original complex single precision by Paul Swarztrauber, Richard Valent.
! Complex double precision version by John Burkardt.
!
! 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 ) ido
integer ( kind = 4 ) in1
integer ( kind = 4 ) in2
integer ( kind = 4 ) l1
real ( kind = 8 ) cc(2,in1,l1,ido,3)
real ( kind = 8 ) ch(2,in2,l1,3,ido)
real ( kind = 8 ) ci2
real ( kind = 8 ) ci3
real ( kind = 8 ) cr2
real ( kind = 8 ) cr3
real ( kind = 8 ) di2
real ( kind = 8 ) di3
real ( kind = 8 ) dr2
real ( kind = 8 ) dr3
integer ( kind = 4 ) i
integer ( kind = 4 ) im1
integer ( kind = 4 ) im2
integer ( kind = 4 ) k
integer ( kind = 4 ) lot
integer ( kind = 4 ) m1
integer ( kind = 4 ) m1d
integer ( kind = 4 ) m2
integer ( kind = 4 ) m2s
integer ( kind = 4 ) na
real ( kind = 8 ) sn
real ( kind = 8 ), parameter :: taui = -0.866025403784439D+00
real ( kind = 8 ), parameter :: taur = -0.5D+00
real ( kind = 8 ) ti2
real ( kind = 8 ) tr2
real ( kind = 8 ) wa(ido,2,2)
m1d = ( lot - 1 ) * im1 + 1
m2s = 1 - im2
if ( 1 < ido ) then
do k = 1, l1
m2 = m2s
do m1 = 1, m1d, im1
m2 = m2 + im2
tr2 = cc(1,m1,k,1,2)+cc(1,m1,k,1,3)
cr2 = cc(1,m1,k,1,1)+taur*tr2
ch(1,m2,k,1,1) = cc(1,m1,k,1,1)+tr2
ti2 = cc(2,m1,k,1,2)+cc(2,m1,k,1,3)
ci2 = cc(2,m1,k,1,1)+taur*ti2
ch(2,m2,k,1,1) = cc(2,m1,k,1,1)+ti2
cr3 = taui*(cc(1,m1,k,1,2)-cc(1,m1,k,1,3))
ci3 = taui*(cc(2,m1,k,1,2)-cc(2,m1,k,1,3))
ch(1,m2,k,2,1) = cr2-ci3
ch(1,m2,k,3,1) = cr2+ci3
ch(2,m2,k,2,1) = ci2+cr3
ch(2,m2,k,3,1) = ci2-cr3
end do
end do
do i = 2, ido
do k = 1, l1
m2 = m2s
do m1 = 1, m1d, im1
m2 = m2 + im2
tr2 = cc(1,m1,k,i,2)+cc(1,m1,k,i,3)
cr2 = cc(1,m1,k,i,1)+taur*tr2
ch(1,m2,k,1,i) = cc(1,m1,k,i,1)+tr2
ti2 = cc(2,m1,k,i,2)+cc(2,m1,k,i,3)
ci2 = cc(2,m1,k,i,1)+taur*ti2
ch(2,m2,k,1,i) = cc(2,m1,k,i,1)+ti2
cr3 = taui*(cc(1,m1,k,i,2)-cc(1,m1,k,i,3))
ci3 = taui*(cc(2,m1,k,i,2)-cc(2,m1,k,i,3))
dr2 = cr2-ci3
dr3 = cr2+ci3
di2 = ci2+cr3
di3 = ci2-cr3
ch(2,m2,k,2,i) = wa(i,1,1)*di2-wa(i,1,2)*dr2
ch(1,m2,k,2,i) = wa(i,1,1)*dr2+wa(i,1,2)*di2
ch(2,m2,k,3,i) = wa(i,2,1)*di3-wa(i,2,2)*dr3
ch(1,m2,k,3,i) = wa(i,2,1)*dr3+wa(i,2,2)*di3
end do
end do
end do
else if ( na == 1 ) then
sn = 1.0D+00 / real ( 3 * l1, kind = 8 )
do k = 1, l1
m2 = m2s
do m1 = 1, m1d, im1
m2 = m2 + im2
tr2 = cc(1,m1,k,1,2)+cc(1,m1,k,1,3)
cr2 = cc(1,m1,k,1,1)+taur*tr2
ch(1,m2,k,1,1) = sn*(cc(1,m1,k,1,1)+tr2)
ti2 = cc(2,m1,k,1,2)+cc(2,m1,k,1,3)
ci2 = cc(2,m1,k,1,1)+taur*ti2
ch(2,m2,k,1,1) = sn*(cc(2,m1,k,1,1)+ti2)
cr3 = taui*(cc(1,m1,k,1,2)-cc(1,m1,k,1,3))
ci3 = taui*(cc(2,m1,k,1,2)-cc(2,m1,k,1,3))
ch(1,m2,k,2,1) = sn*(cr2-ci3)
ch(1,m2,k,3,1) = sn*(cr2+ci3)
ch(2,m2,k,2,1) = sn*(ci2+cr3)
ch(2,m2,k,3,1) = sn*(ci2-cr3)
end do
end do
else
sn = 1.0D+00 / real ( 3 * l1, kind = 8 )
do k = 1, l1
do m1 = 1, m1d, im1
tr2 = cc(1,m1,k,1,2)+cc(1,m1,k,1,3)
cr2 = cc(1,m1,k,1,1)+taur*tr2
cc(1,m1,k,1,1) = sn*(cc(1,m1,k,1,1)+tr2)
ti2 = cc(2,m1,k,1,2)+cc(2,m1,k,1,3)
ci2 = cc(2,m1,k,1,1)+taur*ti2
cc(2,m1,k,1,1) = sn*(cc(2,m1,k,1,1)+ti2)
cr3 = taui*(cc(1,m1,k,1,2)-cc(1,m1,k,1,3))
ci3 = taui*(cc(2,m1,k,1,2)-cc(2,m1,k,1,3))
cc(1,m1,k,1,2) = sn*(cr2-ci3)
cc(1,m1,k,1,3) = sn*(cr2+ci3)
cc(2,m1,k,1,2) = sn*(ci2+cr3)
cc(2,m1,k,1,3) = sn*(ci2-cr3)
end do
end do
end if
return
end