subroutine rfftmf ( lot, jump, n, inc, r, lenr, wsave, lensav, &
work, lenwrk, ier )
!*****************************************************************************80
!
!! RFFTMF: real single precision forward FFT, 1D, multiple vectors.
!
! Discussion:
!
! RFFTMF computes the one-dimensional Fourier transform of multiple
! periodic sequences within a real array. This transform is referred
! to as the forward transform or Fourier analysis, transforming the
! sequences from physical to spectral space.
!
! This transform is normalized since a call to RFFTMF followed
! by a call to RFFTMB (or vice-versa) reproduces the original array
! within roundoff error.
!
! License:
!
! Licensed under the GNU General Public License (GPL).
! Copyright (C) 1995-2004, Scientific Computing Division,
! University Corporation for Atmospheric Research
!
! Modified:
!
! 27 March 2005
!
! 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:
!
! Input, integer ( kind = 4 ) LOT, the number of sequences to be transformed
! within array R.
!
! Input, integer ( kind = 4 ) JUMP, the increment between the locations, in
! array R, of the first elements of two consecutive sequences to be
! transformed.
!
! Input, integer ( kind = 4 ) N, the length of each sequence to be
! transformed. The transform is most efficient when N is a product of
! small primes.
!
! Input, integer ( kind = 4 ) INC, the increment between the locations,
! in array R, of two consecutive elements within the same sequence.
!
! Input/output, real ( kind = 4 ) R(LENR), real array containing LOT
! sequences, each having length N. R can have any number of dimensions, but
! the total number of locations must be at least LENR. On input, the
! physical data to be transformed, on output the spectral data.
!
! Input, integer ( kind = 4 ) LENR, the dimension of the R array.
! LENR must be at least (LOT-1)*JUMP + INC*(N-1) + 1.
!
! Input, real ( kind = 4 ) WSAVE(LENSAV). WSAVE's contents must be
! initialized with a call to RFFTMI before the first call to routine RFFTMF
! or RFFTMB for a given transform length N.
!
! Input, integer ( kind = 4 ) LENSAV, the dimension of the WSAVE array.
! LENSAV must be at least N + INT(LOG(REAL(N))) + 4.
!
! Workspace, real ( kind = 4 ) WORK(LENWRK).
!
! Input, integer ( kind = 4 ) LENWRK, the dimension of the WORK array.
! LENWRK must be at least LOT*N.
!
! Output, integer ( kind = 4 ) IER, error flag.
! 0, successful exit;
! 1, input parameter LENR not big enough;
! 2, input parameter LENSAV not big enough;
! 3, input parameter LENWRK not big enough;
! 4, input parameters INC, JUMP, N, LOT are not consistent.
!
implicit none
integer ( kind = 4 ) lenr
integer ( kind = 4 ) lensav
integer ( kind = 4 ) lenwrk
integer ( kind = 4 ) ier
integer ( kind = 4 ) inc
integer ( kind = 4 ) jump
integer ( kind = 4 ) lot
integer ( kind = 4 ) n
real ( kind = 4 ) r(lenr)
real ( kind = 4 ) work(lenwrk)
real ( kind = 4 ) wsave(lensav)
logical xercon
ier = 0
if ( lenr < ( lot - 1 ) * jump + inc * ( n - 1 ) + 1 ) then
ier = 1
call xerfft ( 'rfftmf ', 6 )
return
end if
if ( lensav < n + int ( log ( real ( n, kind = 4 ) ) ) + 4 ) then
ier = 2
call xerfft ( 'rfftmf ', 8 )
return
end if
if ( lenwrk < lot * n ) then
ier = 3
call xerfft ( 'rfftmf ', 10 )
return
end if
if ( .not. xercon ( inc, jump, n, lot ) ) then
ier = 4
call xerfft ( 'rfftmf ', -1 )
return
end if
if ( n == 1 ) then
return
end if
call mrftf1 ( lot, jump, n, inc, r, work, wsave, wsave(n+1) )
return
end