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905 lines
38 KiB
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905 lines
38 KiB
Text
@node Tutorial, Other Important Topics, Introduction, Top
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@chapter Tutorial
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@menu
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* Complex One-Dimensional DFTs::
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* Complex Multi-Dimensional DFTs::
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* One-Dimensional DFTs of Real Data::
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* Multi-Dimensional DFTs of Real Data::
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* More DFTs of Real Data::
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@end menu
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This chapter describes the basic usage of FFTW, i.e., how to compute
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@cindex basic interface
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the Fourier transform of a single array. This chapter tells the
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truth, but not the @emph{whole} truth. Specifically, FFTW implements
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additional routines and flags that are not documented here, although
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in many cases we try to indicate where added capabilities exist. For
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more complete information, see @ref{FFTW Reference}. (Note that you
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need to compile and install FFTW before you can use it in a program.
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For the details of the installation, see @ref{Installation and
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Customization}.)
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We recommend that you read this tutorial in order.@footnote{You can
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read the tutorial in bit-reversed order after computing your first
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transform.} At the least, read the first section (@pxref{Complex
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One-Dimensional DFTs}) before reading any of the others, even if your
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main interest lies in one of the other transform types.
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Users of FFTW version 2 and earlier may also want to read @ref{Upgrading
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from FFTW version 2}.
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@c ------------------------------------------------------------
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@node Complex One-Dimensional DFTs, Complex Multi-Dimensional DFTs, Tutorial, Tutorial
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@section Complex One-Dimensional DFTs
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@quotation
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Plan: To bother about the best method of accomplishing an accidental result.
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[Ambrose Bierce, @cite{The Enlarged Devil's Dictionary}.]
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@cindex Devil
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@end quotation
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@iftex
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@medskip
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@end iftex
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The basic usage of FFTW to compute a one-dimensional DFT of size
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@code{N} is simple, and it typically looks something like this code:
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@example
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#include <fftw3.h>
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...
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@{
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fftw_complex *in, *out;
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fftw_plan p;
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...
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in = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * N);
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out = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * N);
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p = fftw_plan_dft_1d(N, in, out, FFTW_FORWARD, FFTW_ESTIMATE);
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...
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fftw_execute(p); /* @r{repeat as needed} */
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...
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fftw_destroy_plan(p);
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fftw_free(in); fftw_free(out);
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@}
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@end example
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You must link this code with the @code{fftw3} library. On Unix systems,
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link with @code{-lfftw3 -lm}.
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The example code first allocates the input and output arrays. You can
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allocate them in any way that you like, but we recommend using
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@code{fftw_malloc}, which behaves like
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@findex fftw_malloc
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@code{malloc} except that it properly aligns the array when SIMD
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instructions (such as SSE and Altivec) are available (@pxref{SIMD
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alignment and fftw_malloc}). [Alternatively, we provide a convenient wrapper function @code{fftw_alloc_complex(N)} which has the same effect.]
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@findex fftw_alloc_complex
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@cindex SIMD
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The data is an array of type @code{fftw_complex}, which is by default a
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@code{double[2]} composed of the real (@code{in[i][0]}) and imaginary
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(@code{in[i][1]}) parts of a complex number.
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@tindex fftw_complex
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The next step is to create a @dfn{plan}, which is an object
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@cindex plan
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that contains all the data that FFTW needs to compute the FFT.
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This function creates the plan:
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@example
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fftw_plan fftw_plan_dft_1d(int n, fftw_complex *in, fftw_complex *out,
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int sign, unsigned flags);
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@end example
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@findex fftw_plan_dft_1d
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@tindex fftw_plan
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The first argument, @code{n}, is the size of the transform you are
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trying to compute. The size @code{n} can be any positive integer, but
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sizes that are products of small factors are transformed most
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efficiently (although prime sizes still use an @Onlogn{} algorithm).
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The next two arguments are pointers to the input and output arrays of
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the transform. These pointers can be equal, indicating an
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@dfn{in-place} transform.
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@cindex in-place
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The fourth argument, @code{sign}, can be either @code{FFTW_FORWARD}
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(@code{-1}) or @code{FFTW_BACKWARD} (@code{+1}),
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@ctindex FFTW_FORWARD
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@ctindex FFTW_BACKWARD
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and indicates the direction of the transform you are interested in;
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technically, it is the sign of the exponent in the transform.
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The @code{flags} argument is usually either @code{FFTW_MEASURE} or
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@cindex flags
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@code{FFTW_ESTIMATE}. @code{FFTW_MEASURE} instructs FFTW to run
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@ctindex FFTW_MEASURE
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and measure the execution time of several FFTs in order to find the
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best way to compute the transform of size @code{n}. This process takes
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some time (usually a few seconds), depending on your machine and on
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the size of the transform. @code{FFTW_ESTIMATE}, on the contrary,
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does not run any computation and just builds a
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@ctindex FFTW_ESTIMATE
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reasonable plan that is probably sub-optimal. In short, if your
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program performs many transforms of the same size and initialization
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time is not important, use @code{FFTW_MEASURE}; otherwise use the
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estimate.
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@emph{You must create the plan before initializing the input}, because
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@code{FFTW_MEASURE} overwrites the @code{in}/@code{out} arrays.
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(Technically, @code{FFTW_ESTIMATE} does not touch your arrays, but you
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should always create plans first just to be sure.)
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Once the plan has been created, you can use it as many times as you
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like for transforms on the specified @code{in}/@code{out} arrays,
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computing the actual transforms via @code{fftw_execute(plan)}:
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@example
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void fftw_execute(const fftw_plan plan);
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@end example
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@findex fftw_execute
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The DFT results are stored in-order in the array @code{out}, with the
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zero-frequency (DC) component in @code{out[0]}.
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@cindex frequency
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If @code{in != out}, the transform is @dfn{out-of-place} and the input
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array @code{in} is not modified. Otherwise, the input array is
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overwritten with the transform.
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@cindex execute
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If you want to transform a @emph{different} array of the same size, you
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can create a new plan with @code{fftw_plan_dft_1d} and FFTW
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automatically reuses the information from the previous plan, if
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possible. Alternatively, with the ``guru'' interface you can apply a
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given plan to a different array, if you are careful.
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@xref{FFTW Reference}.
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When you are done with the plan, you deallocate it by calling
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@code{fftw_destroy_plan(plan)}:
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@example
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void fftw_destroy_plan(fftw_plan plan);
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@end example
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@findex fftw_destroy_plan
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If you allocate an array with @code{fftw_malloc()} you must deallocate
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it with @code{fftw_free()}. Do not use @code{free()} or, heaven
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forbid, @code{delete}.
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@findex fftw_free
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FFTW computes an @emph{unnormalized} DFT. Thus, computing a forward
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followed by a backward transform (or vice versa) results in the original
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array scaled by @code{n}. For the definition of the DFT, see @ref{What
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FFTW Really Computes}.
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@cindex DFT
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@cindex normalization
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If you have a C compiler, such as @code{gcc}, that supports the
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C99 standard, and you @code{#include <complex.h>} @emph{before}
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@code{<fftw3.h>}, then @code{fftw_complex} is the native
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double-precision complex type and you can manipulate it with ordinary
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arithmetic. Otherwise, FFTW defines its own complex type, which is
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bit-compatible with the C99 complex type. @xref{Complex numbers}.
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(The C++ @code{<complex>} template class may also be usable via a
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typecast.)
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@cindex C++
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To use single or long-double precision versions of FFTW, replace the
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@code{fftw_} prefix by @code{fftwf_} or @code{fftwl_} and link with
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@code{-lfftw3f} or @code{-lfftw3l}, but use the @emph{same}
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@code{<fftw3.h>} header file.
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@cindex precision
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Many more flags exist besides @code{FFTW_MEASURE} and
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@code{FFTW_ESTIMATE}. For example, use @code{FFTW_PATIENT} if you're
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willing to wait even longer for a possibly even faster plan (@pxref{FFTW
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Reference}).
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@ctindex FFTW_PATIENT
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You can also save plans for future use, as described by @ref{Words of
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Wisdom-Saving Plans}.
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@c ------------------------------------------------------------
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@node Complex Multi-Dimensional DFTs, One-Dimensional DFTs of Real Data, Complex One-Dimensional DFTs, Tutorial
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@section Complex Multi-Dimensional DFTs
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Multi-dimensional transforms work much the same way as one-dimensional
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transforms: you allocate arrays of @code{fftw_complex} (preferably
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using @code{fftw_malloc}), create an @code{fftw_plan}, execute it as
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many times as you want with @code{fftw_execute(plan)}, and clean up
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with @code{fftw_destroy_plan(plan)} (and @code{fftw_free}).
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FFTW provides two routines for creating plans for 2d and 3d transforms,
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and one routine for creating plans of arbitrary dimensionality.
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The 2d and 3d routines have the following signature:
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@example
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fftw_plan fftw_plan_dft_2d(int n0, int n1,
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fftw_complex *in, fftw_complex *out,
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int sign, unsigned flags);
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fftw_plan fftw_plan_dft_3d(int n0, int n1, int n2,
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fftw_complex *in, fftw_complex *out,
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int sign, unsigned flags);
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@end example
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@findex fftw_plan_dft_2d
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@findex fftw_plan_dft_3d
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These routines create plans for @code{n0} by @code{n1} two-dimensional
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(2d) transforms and @code{n0} by @code{n1} by @code{n2} 3d transforms,
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respectively. All of these transforms operate on contiguous arrays in
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the C-standard @dfn{row-major} order, so that the last dimension has the
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fastest-varying index in the array. This layout is described further in
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@ref{Multi-dimensional Array Format}.
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FFTW can also compute transforms of higher dimensionality. In order to
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avoid confusion between the various meanings of the the word
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``dimension'', we use the term @emph{rank}
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@cindex rank
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to denote the number of independent indices in an array.@footnote{The
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term ``rank'' is commonly used in the APL, FORTRAN, and Common Lisp
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traditions, although it is not so common in the C@tie{}world.} For
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example, we say that a 2d transform has rank@tie{}2, a 3d transform has
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rank@tie{}3, and so on. You can plan transforms of arbitrary rank by
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means of the following function:
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@example
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fftw_plan fftw_plan_dft(int rank, const int *n,
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fftw_complex *in, fftw_complex *out,
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int sign, unsigned flags);
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@end example
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@findex fftw_plan_dft
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Here, @code{n} is a pointer to an array @code{n[rank]} denoting an
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@code{n[0]} by @code{n[1]} by @dots{} by @code{n[rank-1]} transform.
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Thus, for example, the call
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@example
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fftw_plan_dft_2d(n0, n1, in, out, sign, flags);
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@end example
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is equivalent to the following code fragment:
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@example
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int n[2];
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n[0] = n0;
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n[1] = n1;
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fftw_plan_dft(2, n, in, out, sign, flags);
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@end example
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@code{fftw_plan_dft} is not restricted to 2d and 3d transforms,
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however, but it can plan transforms of arbitrary rank.
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You may have noticed that all the planner routines described so far
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have overlapping functionality. For example, you can plan a 1d or 2d
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transform by using @code{fftw_plan_dft} with a @code{rank} of @code{1}
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or @code{2}, or even by calling @code{fftw_plan_dft_3d} with @code{n0}
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and/or @code{n1} equal to @code{1} (with no loss in efficiency). This
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pattern continues, and FFTW's planning routines in general form a
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``partial order,'' sequences of
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@cindex partial order
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interfaces with strictly increasing generality but correspondingly
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greater complexity.
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@code{fftw_plan_dft} is the most general complex-DFT routine that we
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describe in this tutorial, but there are also the advanced and guru interfaces,
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@cindex advanced interface
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@cindex guru interface
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which allow one to efficiently combine multiple/strided transforms
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into a single FFTW plan, transform a subset of a larger
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multi-dimensional array, and/or to handle more general complex-number
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formats. For more information, see @ref{FFTW Reference}.
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@c ------------------------------------------------------------
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@node One-Dimensional DFTs of Real Data, Multi-Dimensional DFTs of Real Data, Complex Multi-Dimensional DFTs, Tutorial
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@section One-Dimensional DFTs of Real Data
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In many practical applications, the input data @code{in[i]} are purely
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real numbers, in which case the DFT output satisfies the ``Hermitian''
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@cindex Hermitian
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redundancy: @code{out[i]} is the conjugate of @code{out[n-i]}. It is
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possible to take advantage of these circumstances in order to achieve
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roughly a factor of two improvement in both speed and memory usage.
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In exchange for these speed and space advantages, the user sacrifices
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some of the simplicity of FFTW's complex transforms. First of all, the
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input and output arrays are of @emph{different sizes and types}: the
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input is @code{n} real numbers, while the output is @code{n/2+1}
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complex numbers (the non-redundant outputs); this also requires slight
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``padding'' of the input array for
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@cindex padding
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in-place transforms. Second, the inverse transform (complex to real)
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has the side-effect of @emph{overwriting its input array}, by default.
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Neither of these inconveniences should pose a serious problem for
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users, but it is important to be aware of them.
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The routines to perform real-data transforms are almost the same as
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those for complex transforms: you allocate arrays of @code{double}
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and/or @code{fftw_complex} (preferably using @code{fftw_malloc} or
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@code{fftw_alloc_complex}), create an @code{fftw_plan}, execute it as
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many times as you want with @code{fftw_execute(plan)}, and clean up
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with @code{fftw_destroy_plan(plan)} (and @code{fftw_free}). The only
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differences are that the input (or output) is of type @code{double}
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and there are new routines to create the plan. In one dimension:
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@example
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fftw_plan fftw_plan_dft_r2c_1d(int n, double *in, fftw_complex *out,
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unsigned flags);
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fftw_plan fftw_plan_dft_c2r_1d(int n, fftw_complex *in, double *out,
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unsigned flags);
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@end example
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@findex fftw_plan_dft_r2c_1d
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@findex fftw_plan_dft_c2r_1d
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for the real input to complex-Hermitian output (@dfn{r2c}) and
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complex-Hermitian input to real output (@dfn{c2r}) transforms.
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@cindex r2c
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@cindex c2r
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Unlike the complex DFT planner, there is no @code{sign} argument.
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Instead, r2c DFTs are always @code{FFTW_FORWARD} and c2r DFTs are
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always @code{FFTW_BACKWARD}.
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@ctindex FFTW_FORWARD
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@ctindex FFTW_BACKWARD
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(For single/long-double precision
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@code{fftwf} and @code{fftwl}, @code{double} should be replaced by
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@code{float} and @code{long double}, respectively.)
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@cindex precision
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Here, @code{n} is the ``logical'' size of the DFT, not necessarily the
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physical size of the array. In particular, the real (@code{double})
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array has @code{n} elements, while the complex (@code{fftw_complex})
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array has @code{n/2+1} elements (where the division is rounded down).
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For an in-place transform,
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@cindex in-place
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@code{in} and @code{out} are aliased to the same array, which must be
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big enough to hold both; so, the real array would actually have
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@code{2*(n/2+1)} elements, where the elements beyond the first
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@code{n} are unused padding. (Note that this is very different from
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the concept of ``zero-padding'' a transform to a larger length, which
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changes the logical size of the DFT by actually adding new input
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data.) The @math{k}th element of the complex array is exactly the
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same as the @math{k}th element of the corresponding complex DFT. All
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positive @code{n} are supported; products of small factors are most
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efficient, but an @Onlogn algorithm is used even for prime sizes.
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As noted above, the c2r transform destroys its input array even for
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out-of-place transforms. This can be prevented, if necessary, by
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including @code{FFTW_PRESERVE_INPUT} in the @code{flags}, with
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unfortunately some sacrifice in performance.
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@cindex flags
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@ctindex FFTW_PRESERVE_INPUT
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This flag is also not currently supported for multi-dimensional real
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DFTs (next section).
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Readers familiar with DFTs of real data will recall that the 0th (the
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``DC'') and @code{n/2}-th (the ``Nyquist'' frequency, when @code{n} is
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even) elements of the complex output are purely real. Some
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implementations therefore store the Nyquist element where the DC
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imaginary part would go, in order to make the input and output arrays
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the same size. Such packing, however, does not generalize well to
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multi-dimensional transforms, and the space savings are miniscule in
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any case; FFTW does not support it.
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An alternative interface for one-dimensional r2c and c2r DFTs can be
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found in the @samp{r2r} interface (@pxref{The Halfcomplex-format
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DFT}), with ``halfcomplex''-format output that @emph{is} the same size
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(and type) as the input array.
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@cindex halfcomplex format
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That interface, although it is not very useful for multi-dimensional
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transforms, may sometimes yield better performance.
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@c ------------------------------------------------------------
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@node Multi-Dimensional DFTs of Real Data, More DFTs of Real Data, One-Dimensional DFTs of Real Data, Tutorial
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@section Multi-Dimensional DFTs of Real Data
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Multi-dimensional DFTs of real data use the following planner routines:
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@example
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fftw_plan fftw_plan_dft_r2c_2d(int n0, int n1,
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double *in, fftw_complex *out,
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unsigned flags);
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fftw_plan fftw_plan_dft_r2c_3d(int n0, int n1, int n2,
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double *in, fftw_complex *out,
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unsigned flags);
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fftw_plan fftw_plan_dft_r2c(int rank, const int *n,
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double *in, fftw_complex *out,
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unsigned flags);
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@end example
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@findex fftw_plan_dft_r2c_2d
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@findex fftw_plan_dft_r2c_3d
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@findex fftw_plan_dft_r2c
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as well as the corresponding @code{c2r} routines with the input/output
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types swapped. These routines work similarly to their complex
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analogues, except for the fact that here the complex output array is cut
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roughly in half and the real array requires padding for in-place
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transforms (as in 1d, above).
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As before, @code{n} is the logical size of the array, and the
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consequences of this on the the format of the complex arrays deserve
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careful attention.
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@cindex r2c/c2r multi-dimensional array format
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Suppose that the real data has dimensions @ndims (in row-major order).
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Then, after an r2c transform, the output is an @ndimshalf array of
|
|
@code{fftw_complex} values in row-major order, corresponding to slightly
|
|
over half of the output of the corresponding complex DFT. (The division
|
|
is rounded down.) The ordering of the data is otherwise exactly the
|
|
same as in the complex-DFT case.
|
|
|
|
For out-of-place transforms, this is the end of the story: the real
|
|
data is stored as a row-major array of size @ndims and the complex
|
|
data is stored as a row-major array of size @ndimshalf{}.
|
|
|
|
For in-place transforms, however, extra padding of the real-data array
|
|
is necessary because the complex array is larger than the real array,
|
|
and the two arrays share the same memory locations. Thus, for
|
|
in-place transforms, the final dimension of the real-data array must
|
|
be padded with extra values to accommodate the size of the complex
|
|
data---two values if the last dimension is even and one if it is odd.
|
|
@cindex padding
|
|
That is, the last dimension of the real data must physically contain
|
|
@tex
|
|
$2 (n_{d-1}/2+1)$
|
|
@end tex
|
|
@ifinfo
|
|
2 * (n[d-1]/2+1)
|
|
@end ifinfo
|
|
@html
|
|
2 * (n<sub>d-1</sub>/2+1)
|
|
@end html
|
|
@code{double} values (exactly enough to hold the complex data).
|
|
This physical array size does not, however, change the @emph{logical}
|
|
array size---only
|
|
@tex
|
|
$n_{d-1}$
|
|
@end tex
|
|
@ifinfo
|
|
n[d-1]
|
|
@end ifinfo
|
|
@html
|
|
n<sub>d-1</sub>
|
|
@end html
|
|
values are actually stored in the last dimension, and
|
|
@tex
|
|
$n_{d-1}$
|
|
@end tex
|
|
@ifinfo
|
|
n[d-1]
|
|
@end ifinfo
|
|
@html
|
|
n<sub>d-1</sub>
|
|
@end html
|
|
is the last dimension passed to the plan-creation routine.
|
|
|
|
For example, consider the transform of a two-dimensional real array of
|
|
size @code{n0} by @code{n1}. The output of the r2c transform is a
|
|
two-dimensional complex array of size @code{n0} by @code{n1/2+1}, where
|
|
the @code{y} dimension has been cut nearly in half because of
|
|
redundancies in the output. Because @code{fftw_complex} is twice the
|
|
size of @code{double}, the output array is slightly bigger than the
|
|
input array. Thus, if we want to compute the transform in place, we
|
|
must @emph{pad} the input array so that it is of size @code{n0} by
|
|
@code{2*(n1/2+1)}. If @code{n1} is even, then there are two padding
|
|
elements at the end of each row (which need not be initialized, as they
|
|
are only used for output).
|
|
|
|
@ifhtml
|
|
The following illustration depicts the input and output arrays just
|
|
described, for both the out-of-place and in-place transforms (with the
|
|
arrows indicating consecutive memory locations):
|
|
@image{rfftwnd-for-html}
|
|
@end ifhtml
|
|
@ifnotinfo
|
|
@ifnothtml
|
|
@float Figure,fig:rfftwnd
|
|
@center @image{rfftwnd}
|
|
@caption{Illustration of the data layout for a 2d @code{nx} by @code{ny}
|
|
real-to-complex transform.}
|
|
@end float
|
|
@ref{fig:rfftwnd} depicts the input and output arrays just
|
|
described, for both the out-of-place and in-place transforms (with the
|
|
arrows indicating consecutive memory locations):
|
|
@end ifnothtml
|
|
@end ifnotinfo
|
|
|
|
These transforms are unnormalized, so an r2c followed by a c2r
|
|
transform (or vice versa) will result in the original data scaled by
|
|
the number of real data elements---that is, the product of the
|
|
(logical) dimensions of the real data.
|
|
@cindex normalization
|
|
|
|
|
|
(Because the last dimension is treated specially, if it is equal to
|
|
@code{1} the transform is @emph{not} equivalent to a lower-dimensional
|
|
r2c/c2r transform. In that case, the last complex dimension also has
|
|
size @code{1} (@code{=1/2+1}), and no advantage is gained over the
|
|
complex transforms.)
|
|
|
|
@c ------------------------------------------------------------
|
|
@node More DFTs of Real Data, , Multi-Dimensional DFTs of Real Data, Tutorial
|
|
@section More DFTs of Real Data
|
|
@menu
|
|
* The Halfcomplex-format DFT::
|
|
* Real even/odd DFTs (cosine/sine transforms)::
|
|
* The Discrete Hartley Transform::
|
|
@end menu
|
|
|
|
FFTW supports several other transform types via a unified @dfn{r2r}
|
|
(real-to-real) interface,
|
|
@cindex r2r
|
|
so called because it takes a real (@code{double}) array and outputs a
|
|
real array of the same size. These r2r transforms currently fall into
|
|
three categories: DFTs of real input and complex-Hermitian output in
|
|
halfcomplex format, DFTs of real input with even/odd symmetry
|
|
(a.k.a. discrete cosine/sine transforms, DCTs/DSTs), and discrete
|
|
Hartley transforms (DHTs), all described in more detail by the
|
|
following sections.
|
|
|
|
The r2r transforms follow the by now familiar interface of creating an
|
|
@code{fftw_plan}, executing it with @code{fftw_execute(plan)}, and
|
|
destroying it with @code{fftw_destroy_plan(plan)}. Furthermore, all
|
|
r2r transforms share the same planner interface:
|
|
|
|
@example
|
|
fftw_plan fftw_plan_r2r_1d(int n, double *in, double *out,
|
|
fftw_r2r_kind kind, unsigned flags);
|
|
fftw_plan fftw_plan_r2r_2d(int n0, int n1, double *in, double *out,
|
|
fftw_r2r_kind kind0, fftw_r2r_kind kind1,
|
|
unsigned flags);
|
|
fftw_plan fftw_plan_r2r_3d(int n0, int n1, int n2,
|
|
double *in, double *out,
|
|
fftw_r2r_kind kind0,
|
|
fftw_r2r_kind kind1,
|
|
fftw_r2r_kind kind2,
|
|
unsigned flags);
|
|
fftw_plan fftw_plan_r2r(int rank, const int *n, double *in, double *out,
|
|
const fftw_r2r_kind *kind, unsigned flags);
|
|
@end example
|
|
@findex fftw_plan_r2r_1d
|
|
@findex fftw_plan_r2r_2d
|
|
@findex fftw_plan_r2r_3d
|
|
@findex fftw_plan_r2r
|
|
|
|
Just as for the complex DFT, these plan 1d/2d/3d/multi-dimensional
|
|
transforms for contiguous arrays in row-major order, transforming (real)
|
|
input to output of the same size, where @code{n} specifies the
|
|
@emph{physical} dimensions of the arrays. All positive @code{n} are
|
|
supported (with the exception of @code{n=1} for the @code{FFTW_REDFT00}
|
|
kind, noted in the real-even subsection below); products of small
|
|
factors are most efficient (factorizing @code{n-1} and @code{n+1} for
|
|
@code{FFTW_REDFT00} and @code{FFTW_RODFT00} kinds, described below), but
|
|
an @Onlogn algorithm is used even for prime sizes.
|
|
|
|
Each dimension has a @dfn{kind} parameter, of type
|
|
@code{fftw_r2r_kind}, specifying the kind of r2r transform to be used
|
|
for that dimension.
|
|
@cindex kind (r2r)
|
|
@tindex fftw_r2r_kind
|
|
(In the case of @code{fftw_plan_r2r}, this is an array @code{kind[rank]}
|
|
where @code{kind[i]} is the transform kind for the dimension
|
|
@code{n[i]}.) The kind can be one of a set of predefined constants,
|
|
defined in the following subsections.
|
|
|
|
In other words, FFTW computes the separable product of the specified
|
|
r2r transforms over each dimension, which can be used e.g. for partial
|
|
differential equations with mixed boundary conditions. (For some r2r
|
|
kinds, notably the halfcomplex DFT and the DHT, such a separable
|
|
product is somewhat problematic in more than one dimension, however,
|
|
as is described below.)
|
|
|
|
In the current version of FFTW, all r2r transforms except for the
|
|
halfcomplex type are computed via pre- or post-processing of
|
|
halfcomplex transforms, and they are therefore not as fast as they
|
|
could be. Since most other general DCT/DST codes employ a similar
|
|
algorithm, however, FFTW's implementation should provide at least
|
|
competitive performance.
|
|
|
|
@c =========>
|
|
@node The Halfcomplex-format DFT, Real even/odd DFTs (cosine/sine transforms), More DFTs of Real Data, More DFTs of Real Data
|
|
@subsection The Halfcomplex-format DFT
|
|
|
|
An r2r kind of @code{FFTW_R2HC} (@dfn{r2hc}) corresponds to an r2c DFT
|
|
@ctindex FFTW_R2HC
|
|
@cindex r2c
|
|
@cindex r2hc
|
|
(@pxref{One-Dimensional DFTs of Real Data}) but with ``halfcomplex''
|
|
format output, and may sometimes be faster and/or more convenient than
|
|
the latter.
|
|
@cindex halfcomplex format
|
|
The inverse @dfn{hc2r} transform is of kind @code{FFTW_HC2R}.
|
|
@ctindex FFTW_HC2R
|
|
@cindex hc2r
|
|
This consists of the non-redundant half of the complex output for a 1d
|
|
real-input DFT of size @code{n}, stored as a sequence of @code{n} real
|
|
numbers (@code{double}) in the format:
|
|
|
|
@tex
|
|
$$
|
|
r_0, r_1, r_2, \ldots, r_{n/2}, i_{(n+1)/2-1}, \ldots, i_2, i_1
|
|
$$
|
|
@end tex
|
|
@ifinfo
|
|
r0, r1, r2, r(n/2), i((n+1)/2-1), ..., i2, i1
|
|
@end ifinfo
|
|
@html
|
|
<p align=center>
|
|
r<sub>0</sub>, r<sub>1</sub>, r<sub>2</sub>, ..., r<sub>n/2</sub>, i<sub>(n+1)/2-1</sub>, ..., i<sub>2</sub>, i<sub>1</sub>
|
|
</p>
|
|
@end html
|
|
|
|
Here,
|
|
@ifinfo
|
|
rk
|
|
@end ifinfo
|
|
@tex
|
|
$r_k$
|
|
@end tex
|
|
@html
|
|
r<sub>k</sub>
|
|
@end html
|
|
is the real part of the @math{k}th output, and
|
|
@ifinfo
|
|
ik
|
|
@end ifinfo
|
|
@tex
|
|
$i_k$
|
|
@end tex
|
|
@html
|
|
i<sub>k</sub>
|
|
@end html
|
|
is the imaginary part. (Division by 2 is rounded down.) For a
|
|
halfcomplex array @code{hc[n]}, the @math{k}th component thus has its
|
|
real part in @code{hc[k]} and its imaginary part in @code{hc[n-k]}, with
|
|
the exception of @code{k} @code{==} @code{0} or @code{n/2} (the latter
|
|
only if @code{n} is even)---in these two cases, the imaginary part is
|
|
zero due to symmetries of the real-input DFT, and is not stored.
|
|
Thus, the r2hc transform of @code{n} real values is a halfcomplex array of
|
|
length @code{n}, and vice versa for hc2r.
|
|
@cindex normalization
|
|
|
|
|
|
Aside from the differing format, the output of
|
|
@code{FFTW_R2HC}/@code{FFTW_HC2R} is otherwise exactly the same as for
|
|
the corresponding 1d r2c/c2r transform
|
|
(i.e. @code{FFTW_FORWARD}/@code{FFTW_BACKWARD} transforms, respectively).
|
|
Recall that these transforms are unnormalized, so r2hc followed by hc2r
|
|
will result in the original data multiplied by @code{n}. Furthermore,
|
|
like the c2r transform, an out-of-place hc2r transform will
|
|
@emph{destroy its input} array.
|
|
|
|
Although these halfcomplex transforms can be used with the
|
|
multi-dimensional r2r interface, the interpretation of such a separable
|
|
product of transforms along each dimension is problematic. For example,
|
|
consider a two-dimensional @code{n0} by @code{n1}, r2hc by r2hc
|
|
transform planned by @code{fftw_plan_r2r_2d(n0, n1, in, out, FFTW_R2HC,
|
|
FFTW_R2HC, FFTW_MEASURE)}. Conceptually, FFTW first transforms the rows
|
|
(of size @code{n1}) to produce halfcomplex rows, and then transforms the
|
|
columns (of size @code{n0}). Half of these column transforms, however,
|
|
are of imaginary parts, and should therefore be multiplied by @math{i}
|
|
and combined with the r2hc transforms of the real columns to produce the
|
|
2d DFT amplitudes; FFTW's r2r transform does @emph{not} perform this
|
|
combination for you. Thus, if a multi-dimensional real-input/output DFT
|
|
is required, we recommend using the ordinary r2c/c2r
|
|
interface (@pxref{Multi-Dimensional DFTs of Real Data}).
|
|
|
|
@c =========>
|
|
@node Real even/odd DFTs (cosine/sine transforms), The Discrete Hartley Transform, The Halfcomplex-format DFT, More DFTs of Real Data
|
|
@subsection Real even/odd DFTs (cosine/sine transforms)
|
|
|
|
The Fourier transform of a real-even function @math{f(-x) = f(x)} is
|
|
real-even, and @math{i} times the Fourier transform of a real-odd
|
|
function @math{f(-x) = -f(x)} is real-odd. Similar results hold for a
|
|
discrete Fourier transform, and thus for these symmetries the need for
|
|
complex inputs/outputs is entirely eliminated. Moreover, one gains a
|
|
factor of two in speed/space from the fact that the data are real, and
|
|
an additional factor of two from the even/odd symmetry: only the
|
|
non-redundant (first) half of the array need be stored. The result is
|
|
the real-even DFT (@dfn{REDFT}) and the real-odd DFT (@dfn{RODFT}), also
|
|
known as the discrete cosine and sine transforms (@dfn{DCT} and
|
|
@dfn{DST}), respectively.
|
|
@cindex real-even DFT
|
|
@cindex REDFT
|
|
@cindex real-odd DFT
|
|
@cindex RODFT
|
|
@cindex discrete cosine transform
|
|
@cindex DCT
|
|
@cindex discrete sine transform
|
|
@cindex DST
|
|
|
|
|
|
(In this section, we describe the 1d transforms; multi-dimensional
|
|
transforms are just a separable product of these transforms operating
|
|
along each dimension.)
|
|
|
|
Because of the discrete sampling, one has an additional choice: is the
|
|
data even/odd around a sampling point, or around the point halfway
|
|
between two samples? The latter corresponds to @emph{shifting} the
|
|
samples by @emph{half} an interval, and gives rise to several transform
|
|
variants denoted by REDFT@math{ab} and RODFT@math{ab}: @math{a} and
|
|
@math{b} are @math{0} or @math{1}, and indicate whether the input
|
|
(@math{a}) and/or output (@math{b}) are shifted by half a sample
|
|
(@math{1} means it is shifted). These are also known as types I-IV of
|
|
the DCT and DST, and all four types are supported by FFTW's r2r
|
|
interface.@footnote{There are also type V-VIII transforms, which
|
|
correspond to a logical DFT of @emph{odd} size @math{N}, independent of
|
|
whether the physical size @code{n} is odd, but we do not support these
|
|
variants.}
|
|
|
|
The r2r kinds for the various REDFT and RODFT types supported by FFTW,
|
|
along with the boundary conditions at both ends of the @emph{input}
|
|
array (@code{n} real numbers @code{in[j=0..n-1]}), are:
|
|
|
|
@itemize @bullet
|
|
|
|
@item
|
|
@code{FFTW_REDFT00} (DCT-I): even around @math{j=0} and even around @math{j=n-1}.
|
|
@ctindex FFTW_REDFT00
|
|
|
|
@item
|
|
@code{FFTW_REDFT10} (DCT-II, ``the'' DCT): even around @math{j=-0.5} and even around @math{j=n-0.5}.
|
|
@ctindex FFTW_REDFT10
|
|
|
|
@item
|
|
@code{FFTW_REDFT01} (DCT-III, ``the'' IDCT): even around @math{j=0} and odd around @math{j=n}.
|
|
@ctindex FFTW_REDFT01
|
|
@cindex IDCT
|
|
|
|
@item
|
|
@code{FFTW_REDFT11} (DCT-IV): even around @math{j=-0.5} and odd around @math{j=n-0.5}.
|
|
@ctindex FFTW_REDFT11
|
|
|
|
@item
|
|
@code{FFTW_RODFT00} (DST-I): odd around @math{j=-1} and odd around @math{j=n}.
|
|
@ctindex FFTW_RODFT00
|
|
|
|
@item
|
|
@code{FFTW_RODFT10} (DST-II): odd around @math{j=-0.5} and odd around @math{j=n-0.5}.
|
|
@ctindex FFTW_RODFT10
|
|
|
|
@item
|
|
@code{FFTW_RODFT01} (DST-III): odd around @math{j=-1} and even around @math{j=n-1}.
|
|
@ctindex FFTW_RODFT01
|
|
|
|
@item
|
|
@code{FFTW_RODFT11} (DST-IV): odd around @math{j=-0.5} and even around @math{j=n-0.5}.
|
|
@ctindex FFTW_RODFT11
|
|
|
|
@end itemize
|
|
|
|
Note that these symmetries apply to the ``logical'' array being
|
|
transformed; @strong{there are no constraints on your physical input
|
|
data}. So, for example, if you specify a size-5 REDFT00 (DCT-I) of the
|
|
data @math{abcde}, it corresponds to the DFT of the logical even array
|
|
@math{abcdedcb} of size 8. A size-4 REDFT10 (DCT-II) of the data
|
|
@math{abcd} corresponds to the size-8 logical DFT of the even array
|
|
@math{abcddcba}, shifted by half a sample.
|
|
|
|
All of these transforms are invertible. The inverse of R*DFT00 is
|
|
R*DFT00; of R*DFT10 is R*DFT01 and vice versa (these are often called
|
|
simply ``the'' DCT and IDCT, respectively); and of R*DFT11 is R*DFT11.
|
|
However, the transforms computed by FFTW are unnormalized, exactly
|
|
like the corresponding real and complex DFTs, so computing a transform
|
|
followed by its inverse yields the original array scaled by @math{N},
|
|
where @math{N} is the @emph{logical} DFT size. For REDFT00,
|
|
@math{N=2(n-1)}; for RODFT00, @math{N=2(n+1)}; otherwise, @math{N=2n}.
|
|
@cindex normalization
|
|
@cindex IDCT
|
|
|
|
|
|
Note that the boundary conditions of the transform output array are
|
|
given by the input boundary conditions of the inverse transform.
|
|
Thus, the above transforms are all inequivalent in terms of
|
|
input/output boundary conditions, even neglecting the 0.5 shift
|
|
difference.
|
|
|
|
FFTW is most efficient when @math{N} is a product of small factors; note
|
|
that this @emph{differs} from the factorization of the physical size
|
|
@code{n} for REDFT00 and RODFT00! There is another oddity: @code{n=1}
|
|
REDFT00 transforms correspond to @math{N=0}, and so are @emph{not
|
|
defined} (the planner will return @code{NULL}). Otherwise, any positive
|
|
@code{n} is supported.
|
|
|
|
For the precise mathematical definitions of these transforms as used by
|
|
FFTW, see @ref{What FFTW Really Computes}. (For people accustomed to
|
|
the DCT/DST, FFTW's definitions have a coefficient of @math{2} in front
|
|
of the cos/sin functions so that they correspond precisely to an
|
|
even/odd DFT of size @math{N}. Some authors also include additional
|
|
multiplicative factors of
|
|
@ifinfo
|
|
sqrt(2)
|
|
@end ifinfo
|
|
@html
|
|
√2
|
|
@end html
|
|
@tex
|
|
$\sqrt{2}$
|
|
@end tex
|
|
for selected inputs and outputs; this makes
|
|
the transform orthogonal, but sacrifices the direct equivalence to a
|
|
symmetric DFT.)
|
|
|
|
@subsubheading Which type do you need?
|
|
|
|
Since the required flavor of even/odd DFT depends upon your problem,
|
|
you are the best judge of this choice, but we can make a few comments
|
|
on relative efficiency to help you in your selection. In particular,
|
|
R*DFT01 and R*DFT10 tend to be slightly faster than R*DFT11
|
|
(especially for odd sizes), while the R*DFT00 transforms are sometimes
|
|
significantly slower (especially for even sizes).@footnote{R*DFT00 is
|
|
sometimes slower in FFTW because we discovered that the standard
|
|
algorithm for computing this by a pre/post-processed real DFT---the
|
|
algorithm used in FFTPACK, Numerical Recipes, and other sources for
|
|
decades now---has serious numerical problems: it already loses several
|
|
decimal places of accuracy for 16k sizes. There seem to be only two
|
|
alternatives in the literature that do not suffer similarly: a
|
|
recursive decomposition into smaller DCTs, which would require a large
|
|
set of codelets for efficiency and generality, or sacrificing a factor of
|
|
@tex
|
|
$\sim 2$
|
|
@end tex
|
|
@ifnottex
|
|
2
|
|
@end ifnottex
|
|
in speed to use a real DFT of twice the size. We currently
|
|
employ the latter technique for general @math{n}, as well as a limited
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form of the former method: a split-radix decomposition when @math{n}
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is odd (@math{N} a multiple of 4). For @math{N} containing many
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factors of 2, the split-radix method seems to recover most of the
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speed of the standard algorithm without the accuracy tradeoff.}
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Thus, if only the boundary conditions on the transform inputs are
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specified, we generally recommend R*DFT10 over R*DFT00 and R*DFT01 over
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R*DFT11 (unless the half-sample shift or the self-inverse property is
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significant for your problem).
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If performance is important to you and you are using only small sizes
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(say @math{n<200}), e.g. for multi-dimensional transforms, then you
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might consider generating hard-coded transforms of those sizes and types
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that you are interested in (@pxref{Generating your own code}).
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We are interested in hearing what types of symmetric transforms you find
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most useful.
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@c =========>
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@node The Discrete Hartley Transform, , Real even/odd DFTs (cosine/sine transforms), More DFTs of Real Data
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@subsection The Discrete Hartley Transform
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If you are planning to use the DHT because you've heard that it is
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``faster'' than the DFT (FFT), @strong{stop here}. The DHT is not
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faster than the DFT. That story is an old but enduring misconception
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that was debunked in 1987.
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The discrete Hartley transform (DHT) is an invertible linear transform
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closely related to the DFT. In the DFT, one multiplies each input by
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@math{cos - i * sin} (a complex exponential), whereas in the DHT each
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input is multiplied by simply @math{cos + sin}. Thus, the DHT
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transforms @code{n} real numbers to @code{n} real numbers, and has the
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convenient property of being its own inverse. In FFTW, a DHT (of any
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positive @code{n}) can be specified by an r2r kind of @code{FFTW_DHT}.
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@ctindex FFTW_DHT
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@cindex discrete Hartley transform
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@cindex DHT
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Like the DFT, in FFTW the DHT is unnormalized, so computing a DHT of
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size @code{n} followed by another DHT of the same size will result in
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the original array multiplied by @code{n}.
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@cindex normalization
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The DHT was originally proposed as a more efficient alternative to the
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DFT for real data, but it was subsequently shown that a specialized DFT
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(such as FFTW's r2hc or r2c transforms) could be just as fast. In FFTW,
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the DHT is actually computed by post-processing an r2hc transform, so
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there is ordinarily no reason to prefer it from a performance
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perspective.@footnote{We provide the DHT mainly as a byproduct of some
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internal algorithms. FFTW computes a real input/output DFT of
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@emph{prime} size by re-expressing it as a DHT plus post/pre-processing
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and then using Rader's prime-DFT algorithm adapted to the DHT.}
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However, we have heard rumors that the DHT might be the most appropriate
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transform in its own right for certain applications, and we would be
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very interested to hear from anyone who finds it useful.
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If @code{FFTW_DHT} is specified for multiple dimensions of a
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multi-dimensional transform, FFTW computes the separable product of 1d
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DHTs along each dimension. Unfortunately, this is not quite the same
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thing as a true multi-dimensional DHT; you can compute the latter, if
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necessary, with at most @code{rank-1} post-processing passes
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[see e.g. H. Hao and R. N. Bracewell, @i{Proc. IEEE} @b{75}, 264--266 (1987)].
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For the precise mathematical definition of the DHT as used by FFTW, see
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@ref{What FFTW Really Computes}.
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