Node:Advanced Real-data DFTs, Next:Advanced Real-to-real Transforms, Previous:Advanced Complex DFTs, Up:Advanced Interface
fftw_plan fftw_plan_many_dft_r2c(int rank, const int *n, int howmany, double *in, const int *inembed, int istride, int idist, fftw_complex *out, const int *onembed, int ostride, int odist, unsigned flags); fftw_plan fftw_plan_many_dft_c2r(int rank, const int *n, int howmany, fftw_complex *in, const int *inembed, int istride, int idist, double *out, const int *onembed, int ostride, int odist, unsigned flags);
Like fftw_plan_many_dft
, these two functions add howmany
,
nembed
, stride
, and dist
parameters to the
fftw_plan_dft_r2c
and fftw_plan_dft_c2r
functions, but
otherwise behave the same as the basic interface.
The interpretation of howmany
, stride
, and dist
are
the same as for fftw_plan_many_dft
, above. Note that the
stride
and dist
for the real array are in units of
double
, and for the complex array are in units of
fftw_complex
.
If an nembed
parameter is NULL
, it is interpreted as what
it would be in the basic interface, as described in Real-data DFT Array Format. That is, for the complex array the size is assumed to be
the same as n
, but with the last dimension cut roughly in half.
For the real array, the size is assumed to be n
if the transform
is out-of-place, or n
with the last dimension "padded" if the
transform is in-place.
If an nembed
parameter is non-NULL
, it is interpreted as
the physical size of the corresponding array, in row-major order, just
as for fftw_plan_many_dft
. In this case, each dimension of
nembed
should be >=
what it would be in the basic
interface (e.g. the halved or padded n
).