subroutine zfftmf ( lot, jump, n, inc, c, lenc, wsave, lensav, work, & lenwrk, ier ) !*****************************************************************************80 ! !! ZFFTMF: complex double precision forward FFT, 1D, multiple vectors. ! ! Discussion: ! ! ZFFTMF computes the one-dimensional Fourier transform of multiple ! periodic sequences within a complex 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 ZFFTMF followed by a call to ZFFTMB ! (or vice-versa) reproduces the original array within roundoff error. ! ! The parameters integers INC, JUMP, N and LOT are consistent if equality ! I1*INC + J1*JUMP = I2*INC + J2*JUMP for I1,I2 < N and J1,J2 < LOT ! implies I1=I2 and J1=J2. For multiple FFTs to execute correctly, ! input variables INC, JUMP, N and LOT must be consistent, otherwise ! at least one array element mistakenly is transformed more than once. ! ! ! ! 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: ! ! Input, integer ( kind = 4 ) LOT, the number of sequences to be ! transformed within array C. ! ! Input, integer ( kind = 4 ) JUMP, the increment between the locations, ! in array C, 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 C, of two consecutive elements within the same sequence to be ! transformed. ! ! Input/output, complex ( kind = 8 ) C(LENC), array containing LOT sequences, ! each having length N, to be transformed. C can have any number of ! dimensions, but the total number of locations must be at least LENC. ! ! Input, integer ( kind = 4 ) LENC, the dimension of the C array. ! LENC must be at least (LOT-1)*JUMP + INC*(N-1) + 1. ! ! Input, real ( kind = 8 ) WSAVE(LENSAV). WSAVE's contents must be ! initialized with a call to ZFFTMI before the first call to routine ZFFTMF ! or ZFFTMB for a given transform length N. ! ! Input, integer ( kind = 4 ) LENSAV, the dimension of the WSAVE array. ! LENSAV must be at least 2*N + INT(LOG(REAL(N))) + 4. ! ! Workspace, real ( kind = 8 ) WORK(LENWRK). ! ! Input, integer ( kind = 4 ) LENWRK, the dimension of the WORK array. ! LENWRK must be at least 2*LOT*N. ! ! Output, integer ( kind = 4 ) IER, error flag. ! 0 successful exit; ! 1 input parameter LENC 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 ) lenc integer ( kind = 4 ) lensav integer ( kind = 4 ) lenwrk complex ( kind = 8 ) c(lenc) integer ( kind = 4 ) ier integer ( kind = 4 ) inc integer ( kind = 4 ) iw1 integer ( kind = 4 ) jump integer ( kind = 4 ) lot integer ( kind = 4 ) n real ( kind = 8 ) work(lenwrk) real ( kind = 8 ) wsave(lensav) logical xercon ier = 0 if ( lenc < ( lot - 1 ) * jump + inc * ( n - 1 ) + 1 ) then ier = 1 call xerfft ( 'ZFFTMF', 6 ) return end if if ( lensav < 2 * n + int ( log ( real ( n, kind = 8 ) ) ) + 4 ) then ier = 2 call xerfft ( 'ZFFTMF', 8 ) return end if if ( lenwrk < 2 * lot * n ) then ier = 3 call xerfft ( 'ZFFTMF', 10 ) return end if if ( .not. xercon ( inc, jump, n, lot ) ) then ier = 4 call xerfft ( 'ZFFTMF', -1 ) return end if if ( n == 1 ) then return end if iw1 = n + n + 1 call zmfm1f ( lot, jump, n, inc, c, work, wsave, wsave(iw1), & wsave(iw1+1) ) return end