sv-dependency-builds: src/fftw-3.3.8/doc/legacy-fortran.texi annotate

annotate src/fftw-3.3.8/doc/legacy-fortran.texi @ 169:223a55898ab9 tip default

Add null config files

author	Chris Cannam <cannam@all-day-breakfast.com>
date	Mon, 02 Mar 2020 14:03:47 +0000
parents	bd3cc4d1df30
children

rev	line source
cannam@167	1 @node Calling FFTW from Legacy Fortran, Upgrading from FFTW version 2, Calling FFTW from Modern Fortran, Top
cannam@167	2 @chapter Calling FFTW from Legacy Fortran
cannam@167	3 @cindex Fortran interface
cannam@167	4
cannam@167	5 This chapter describes the interface to FFTW callable by Fortran code
cannam@167	6 in older compilers not supporting the Fortran 2003 C interoperability
cannam@167	7 features (@pxref{Calling FFTW from Modern Fortran}). This interface
cannam@167	8 has the major disadvantage that it is not type-checked, so if you
cannam@167	9 mistake the argument types or ordering then your program will not have
cannam@167	10 any compiler errors, and will likely crash at runtime. So, greater
cannam@167	11 care is needed. Also, technically interfacing older Fortran versions
cannam@167	12 to C is nonstandard, but in practice we have found that the techniques
cannam@167	13 used in this chapter have worked with all known Fortran compilers for
cannam@167	14 many years.
cannam@167	15
cannam@167	16 The legacy Fortran interface differs from the C interface only in the
cannam@167	17 prefix (@samp{dfftw_} instead of @samp{fftw_} in double precision) and
cannam@167	18 a few other minor details. This Fortran interface is included in the
cannam@167	19 FFTW libraries by default, unless a Fortran compiler isn't found on
cannam@167	20 your system or @code{--disable-fortran} is included in the
cannam@167	21 @code{configure} flags. We assume here that the reader is already
cannam@167	22 familiar with the usage of FFTW in C, as described elsewhere in this
cannam@167	23 manual.
cannam@167	24
cannam@167	25 The MPI parallel interface to FFTW is @emph{not} currently available
cannam@167	26 to legacy Fortran.
cannam@167	27
cannam@167	28 @menu
cannam@167	29 * Fortran-interface routines::
cannam@167	30 * FFTW Constants in Fortran::
cannam@167	31 * FFTW Execution in Fortran::
cannam@167	32 * Fortran Examples::
cannam@167	33 * Wisdom of Fortran?::
cannam@167	34 @end menu
cannam@167	35
cannam@167	36 @c -------------------------------------------------------
cannam@167	37 @node Fortran-interface routines, FFTW Constants in Fortran, Calling FFTW from Legacy Fortran, Calling FFTW from Legacy Fortran
cannam@167	38 @section Fortran-interface routines
cannam@167	39
cannam@167	40 Nearly all of the FFTW functions have Fortran-callable equivalents.
cannam@167	41 The name of the legacy Fortran routine is the same as that of the
cannam@167	42 corresponding C routine, but with the @samp{fftw_} prefix replaced by
cannam@167	43 @samp{dfftw_}.@footnote{Technically, Fortran 77 identifiers are not
cannam@167	44 allowed to have more than 6 characters, nor may they contain
cannam@167	45 underscores. Any compiler that enforces this limitation doesn't
cannam@167	46 deserve to link to FFTW.} The single and long-double precision
cannam@167	47 versions use @samp{sfftw_} and @samp{lfftw_}, respectively, instead of
cannam@167	48 @samp{fftwf_} and @samp{fftwl_}; quadruple precision (@code{real*16})
cannam@167	49 is available on some systems as @samp{fftwq_} (@pxref{Precision}).
cannam@167	50 (Note that @code{long double} on x86 hardware is usually at most
cannam@167	51 80-bit extended precision, @emph{not} quadruple precision.)
cannam@167	52
cannam@167	53 For the most part, all of the arguments to the functions are the same,
cannam@167	54 with the following exceptions:
cannam@167	55
cannam@167	56 @itemize @bullet
cannam@167	57
cannam@167	58 @item
cannam@167	59 @code{plan} variables (what would be of type @code{fftw_plan} in C),
cannam@167	60 must be declared as a type that is at least as big as a pointer
cannam@167	61 (address) on your machine. We recommend using @code{integer*8} everywhere,
cannam@167	62 since this should always be big enough.
cannam@167	63 @cindex portability
cannam@167	64
cannam@167	65 @item
cannam@167	66 Any function that returns a value (e.g. @code{fftw_plan_dft}) is
cannam@167	67 converted into a @emph{subroutine}. The return value is converted into
cannam@167	68 an additional @emph{first} parameter of this subroutine.@footnote{The
cannam@167	69 reason for this is that some Fortran implementations seem to have
cannam@167	70 trouble with C function return values, and vice versa.}
cannam@167	71
cannam@167	72 @item
cannam@167	73 @cindex column-major
cannam@167	74 The Fortran routines expect multi-dimensional arrays to be in
cannam@167	75 @emph{column-major} order, which is the ordinary format of Fortran
cannam@167	76 arrays (@pxref{Multi-dimensional Array Format}). They do this
cannam@167	77 transparently and costlessly simply by reversing the order of the
cannam@167	78 dimensions passed to FFTW, but this has one important consequence for
cannam@167	79 multi-dimensional real-complex transforms, discussed below.
cannam@167	80
cannam@167	81 @item
cannam@167	82 Wisdom import and export is somewhat more tricky because one cannot
cannam@167	83 easily pass files or strings between C and Fortran; see @ref{Wisdom of
cannam@167	84 Fortran?}.
cannam@167	85
cannam@167	86 @item
cannam@167	87 Legacy Fortran cannot use the @code{fftw_malloc} dynamic-allocation routine.
cannam@167	88 If you want to exploit the SIMD FFTW (@pxref{SIMD alignment and fftw_malloc}), you'll
cannam@167	89 need to figure out some other way to ensure that your arrays are at
cannam@167	90 least 16-byte aligned.
cannam@167	91
cannam@167	92 @item
cannam@167	93 @tindex fftw_iodim
cannam@167	94 @cindex guru interface
cannam@167	95 Since Fortran 77 does not have data structures, the @code{fftw_iodim}
cannam@167	96 structure from the guru interface (@pxref{Guru vector and transform
cannam@167	97 sizes}) must be split into separate arguments. In particular, any
cannam@167	98 @code{fftw_iodim} array arguments in the C guru interface become three
cannam@167	99 integer array arguments (@code{n}, @code{is}, and @code{os}) in the
cannam@167	100 Fortran guru interface, all of whose lengths should be equal to the
cannam@167	101 corresponding @code{rank} argument.
cannam@167	102
cannam@167	103 @item
cannam@167	104 The guru planner interface in Fortran does @emph{not} do any automatic
cannam@167	105 translation between column-major and row-major; you are responsible
cannam@167	106 for setting the strides etcetera to correspond to your Fortran arrays.
cannam@167	107 However, as a slight bug that we are preserving for backwards
cannam@167	108 compatibility, the @samp{plan_guru_r2r} in Fortran @emph{does} reverse the
cannam@167	109 order of its @code{kind} array parameter, so the @code{kind} array
cannam@167	110 of that routine should be in the reverse of the order of the iodim
cannam@167	111 arrays (see above).
cannam@167	112
cannam@167	113 @end itemize
cannam@167	114
cannam@167	115 In general, you should take care to use Fortran data types that
cannam@167	116 correspond to (i.e. are the same size as) the C types used by FFTW.
cannam@167	117 In practice, this correspondence is usually straightforward
cannam@167	118 (i.e. @code{integer} corresponds to @code{int}, @code{real}
cannam@167	119 corresponds to @code{float}, etcetera). The native Fortran
cannam@167	120 double/single-precision complex type should be compatible with
cannam@167	121 @code{fftw_complex}/@code{fftwf_complex}. Such simple correspondences
cannam@167	122 are assumed in the examples below.
cannam@167	123 @cindex portability
cannam@167	124
cannam@167	125 @c -------------------------------------------------------
cannam@167	126 @node FFTW Constants in Fortran, FFTW Execution in Fortran, Fortran-interface routines, Calling FFTW from Legacy Fortran
cannam@167	127 @section FFTW Constants in Fortran
cannam@167	128
cannam@167	129 When creating plans in FFTW, a number of constants are used to specify
cannam@167	130 options, such as @code{FFTW_MEASURE} or @code{FFTW_ESTIMATE}. The
cannam@167	131 same constants must be used with the wrapper routines, but of course the
cannam@167	132 C header files where the constants are defined can't be incorporated
cannam@167	133 directly into Fortran code.
cannam@167	134
cannam@167	135 Instead, we have placed Fortran equivalents of the FFTW constant
cannam@167	136 definitions in the file @code{fftw3.f}, which can be found in the same
cannam@167	137 directory as @code{fftw3.h}. If your Fortran compiler supports a
cannam@167	138 preprocessor of some sort, you should be able to @code{include} or
cannam@167	139 @code{#include} this file; otherwise, you can paste it directly into
cannam@167	140 your code.
cannam@167	141
cannam@167	142 @cindex flags
cannam@167	143 In C, you combine different flags (like @code{FFTW_PRESERVE_INPUT} and
cannam@167	144 @code{FFTW_MEASURE}) using the @samp{@code{\|}} operator; in Fortran
cannam@167	145 you should just use @samp{@code{+}}. (Take care not to add in the
cannam@167	146 same flag more than once, though. Alternatively, you can use the
cannam@167	147 @code{ior} intrinsic function standardized in Fortran 95.)
cannam@167	148
cannam@167	149 @c -------------------------------------------------------
cannam@167	150 @node FFTW Execution in Fortran, Fortran Examples, FFTW Constants in Fortran, Calling FFTW from Legacy Fortran
cannam@167	151 @section FFTW Execution in Fortran
cannam@167	152
cannam@167	153 In C, in order to use a plan, one normally calls @code{fftw_execute},
cannam@167	154 which executes the plan to perform the transform on the input/output
cannam@167	155 arrays passed when the plan was created (@pxref{Using Plans}). The
cannam@167	156 corresponding subroutine call in legacy Fortran is:
cannam@167	157 @example
cannam@167	158 call dfftw_execute(plan)
cannam@167	159 @end example
cannam@167	160 @findex dfftw_execute
cannam@167	161
cannam@167	162 However, we have had reports that this causes problems with some
cannam@167	163 recent optimizing Fortran compilers. The problem is, because the
cannam@167	164 input/output arrays are not passed as explicit arguments to
cannam@167	165 @code{dfftw_execute}, the semantics of Fortran (unlike C) allow the
cannam@167	166 compiler to assume that the input/output arrays are not changed by
cannam@167	167 @code{dfftw_execute}. As a consequence, certain compilers end up
cannam@167	168 optimizing out or repositioning the call to @code{dfftw_execute},
cannam@167	169 assuming incorrectly that it does nothing.
cannam@167	170
cannam@167	171 There are various workarounds to this, but the safest and simplest
cannam@167	172 thing is to not use @code{dfftw_execute} in Fortran. Instead, use the
cannam@167	173 functions described in @ref{New-array Execute Functions}, which take
cannam@167	174 the input/output arrays as explicit arguments. For example, if the
cannam@167	175 plan is for a complex-data DFT and was created for the arrays
cannam@167	176 @code{in} and @code{out}, you would do:
cannam@167	177 @example
cannam@167	178 call dfftw_execute_dft(plan, in, out)
cannam@167	179 @end example
cannam@167	180 @findex dfftw_execute_dft
cannam@167	181
cannam@167	182 There are a few things to be careful of, however:
cannam@167	183
cannam@167	184 @itemize @bullet
cannam@167	185
cannam@167	186 @item
cannam@167	187 You must use the correct type of execute function, matching the way
cannam@167	188 the plan was created. Complex DFT plans should use
cannam@167	189 @code{dfftw_execute_dft}, Real-input (r2c) DFT plans should use use
cannam@167	190 @code{dfftw_execute_dft_r2c}, and real-output (c2r) DFT plans should
cannam@167	191 use @code{dfftw_execute_dft_c2r}. The various r2r plans should use
cannam@167	192 @code{dfftw_execute_r2r}.
cannam@167	193
cannam@167	194 @item
cannam@167	195 You should normally pass the same input/output arrays that were used when
cannam@167	196 creating the plan. This is always safe.
cannam@167	197
cannam@167	198 @item
cannam@167	199 @emph{If} you pass @emph{different} input/output arrays compared to
cannam@167	200 those used when creating the plan, you must abide by all the
cannam@167	201 restrictions of the new-array execute functions (@pxref{New-array
cannam@167	202 Execute Functions}). The most difficult of these, in Fortran, is the
cannam@167	203 requirement that the new arrays have the same alignment as the
cannam@167	204 original arrays, because there seems to be no way in legacy Fortran to obtain
cannam@167	205 guaranteed-aligned arrays (analogous to @code{fftw_malloc} in C). You
cannam@167	206 can, of course, use the @code{FFTW_UNALIGNED} flag when creating the
cannam@167	207 plan, in which case the plan does not depend on the alignment, but
cannam@167	208 this may sacrifice substantial performance on architectures (like x86)
cannam@167	209 with SIMD instructions (@pxref{SIMD alignment and fftw_malloc}).
cannam@167	210 @ctindex FFTW_UNALIGNED
cannam@167	211
cannam@167	212 @end itemize
cannam@167	213
cannam@167	214 @c -------------------------------------------------------
cannam@167	215 @node Fortran Examples, Wisdom of Fortran?, FFTW Execution in Fortran, Calling FFTW from Legacy Fortran
cannam@167	216 @section Fortran Examples
cannam@167	217
cannam@167	218 In C, you might have something like the following to transform a
cannam@167	219 one-dimensional complex array:
cannam@167	220
cannam@167	221 @example
cannam@167	222 fftw_complex in[N], out[N];
cannam@167	223 fftw_plan plan;
cannam@167	224
cannam@167	225 plan = fftw_plan_dft_1d(N,in,out,FFTW_FORWARD,FFTW_ESTIMATE);
cannam@167	226 fftw_execute(plan);
cannam@167	227 fftw_destroy_plan(plan);
cannam@167	228 @end example
cannam@167	229
cannam@167	230 In Fortran, you would use the following to accomplish the same thing:
cannam@167	231
cannam@167	232 @example
cannam@167	233 double complex in, out
cannam@167	234 dimension in(N), out(N)
cannam@167	235 integer*8 plan
cannam@167	236
cannam@167	237 call dfftw_plan_dft_1d(plan,N,in,out,FFTW_FORWARD,FFTW_ESTIMATE)
cannam@167	238 call dfftw_execute_dft(plan, in, out)
cannam@167	239 call dfftw_destroy_plan(plan)
cannam@167	240 @end example
cannam@167	241 @findex dfftw_plan_dft_1d
cannam@167	242 @findex dfftw_execute_dft
cannam@167	243 @findex dfftw_destroy_plan
cannam@167	244
cannam@167	245 Notice how all routines are called as Fortran subroutines, and the
cannam@167	246 plan is returned via the first argument to @code{dfftw_plan_dft_1d}.
cannam@167	247 Notice also that we changed @code{fftw_execute} to
cannam@167	248 @code{dfftw_execute_dft} (@pxref{FFTW Execution in Fortran}). To do
cannam@167	249 the same thing, but using 8 threads in parallel (@pxref{Multi-threaded
cannam@167	250 FFTW}), you would simply prefix these calls with:
cannam@167	251
cannam@167	252 @example
cannam@167	253 integer iret
cannam@167	254 call dfftw_init_threads(iret)
cannam@167	255 call dfftw_plan_with_nthreads(8)
cannam@167	256 @end example
cannam@167	257 @findex dfftw_init_threads
cannam@167	258 @findex dfftw_plan_with_nthreads
cannam@167	259
cannam@167	260 (You might want to check the value of @code{iret}: if it is zero, it
cannam@167	261 indicates an unlikely error during thread initialization.)
cannam@167	262
cannam@167	263 To transform a three-dimensional array in-place with C, you might do:
cannam@167	264
cannam@167	265 @example
cannam@167	266 fftw_complex arr[L][M][N];
cannam@167	267 fftw_plan plan;
cannam@167	268
cannam@167	269 plan = fftw_plan_dft_3d(L,M,N, arr,arr,
cannam@167	270 FFTW_FORWARD, FFTW_ESTIMATE);
cannam@167	271 fftw_execute(plan);
cannam@167	272 fftw_destroy_plan(plan);
cannam@167	273 @end example
cannam@167	274
cannam@167	275 In Fortran, you would use this instead:
cannam@167	276
cannam@167	277 @example
cannam@167	278 double complex arr
cannam@167	279 dimension arr(L,M,N)
cannam@167	280 integer*8 plan
cannam@167	281
cannam@167	282 call dfftw_plan_dft_3d(plan, L,M,N, arr,arr,
cannam@167	283 & FFTW_FORWARD, FFTW_ESTIMATE)
cannam@167	284 call dfftw_execute_dft(plan, arr, arr)
cannam@167	285 call dfftw_destroy_plan(plan)
cannam@167	286 @end example
cannam@167	287 @findex dfftw_plan_dft_3d
cannam@167	288
cannam@167	289 Note that we pass the array dimensions in the ``natural'' order in both C
cannam@167	290 and Fortran.
cannam@167	291
cannam@167	292 To transform a one-dimensional real array in Fortran, you might do:
cannam@167	293
cannam@167	294 @example
cannam@167	295 double precision in
cannam@167	296 dimension in(N)
cannam@167	297 double complex out
cannam@167	298 dimension out(N/2 + 1)
cannam@167	299 integer*8 plan
cannam@167	300
cannam@167	301 call dfftw_plan_dft_r2c_1d(plan,N,in,out,FFTW_ESTIMATE)
cannam@167	302 call dfftw_execute_dft_r2c(plan, in, out)
cannam@167	303 call dfftw_destroy_plan(plan)
cannam@167	304 @end example
cannam@167	305 @findex dfftw_plan_dft_r2c_1d
cannam@167	306 @findex dfftw_execute_dft_r2c
cannam@167	307
cannam@167	308 To transform a two-dimensional real array, out of place, you might use
cannam@167	309 the following:
cannam@167	310
cannam@167	311 @example
cannam@167	312 double precision in
cannam@167	313 dimension in(M,N)
cannam@167	314 double complex out
cannam@167	315 dimension out(M/2 + 1, N)
cannam@167	316 integer*8 plan
cannam@167	317
cannam@167	318 call dfftw_plan_dft_r2c_2d(plan,M,N,in,out,FFTW_ESTIMATE)
cannam@167	319 call dfftw_execute_dft_r2c(plan, in, out)
cannam@167	320 call dfftw_destroy_plan(plan)
cannam@167	321 @end example
cannam@167	322 @findex dfftw_plan_dft_r2c_2d
cannam@167	323
cannam@167	324 @strong{Important:} Notice that it is the @emph{first} dimension of the
cannam@167	325 complex output array that is cut in half in Fortran, rather than the
cannam@167	326 last dimension as in C. This is a consequence of the interface routines
cannam@167	327 reversing the order of the array dimensions passed to FFTW so that the
cannam@167	328 Fortran program can use its ordinary column-major order.
cannam@167	329 @cindex column-major
cannam@167	330 @cindex r2c/c2r multi-dimensional array format
cannam@167	331
cannam@167	332 @c -------------------------------------------------------
cannam@167	333 @node Wisdom of Fortran?, , Fortran Examples, Calling FFTW from Legacy Fortran
cannam@167	334 @section Wisdom of Fortran?
cannam@167	335
cannam@167	336 In this section, we discuss how one can import/export FFTW wisdom
cannam@167	337 (saved plans) to/from a Fortran program; we assume that the reader is
cannam@167	338 already familiar with wisdom, as described in @ref{Words of
cannam@167	339 Wisdom-Saving Plans}.
cannam@167	340
cannam@167	341 @cindex portability
cannam@167	342 The basic problem is that is difficult to (portably) pass files and
cannam@167	343 strings between Fortran and C, so we cannot provide a direct Fortran
cannam@167	344 equivalent to the @code{fftw_export_wisdom_to_file}, etcetera,
cannam@167	345 functions. Fortran interfaces @emph{are} provided for the functions
cannam@167	346 that do not take file/string arguments, however:
cannam@167	347 @code{dfftw_import_system_wisdom}, @code{dfftw_import_wisdom},
cannam@167	348 @code{dfftw_export_wisdom}, and @code{dfftw_forget_wisdom}.
cannam@167	349 @findex dfftw_import_system_wisdom
cannam@167	350 @findex dfftw_import_wisdom
cannam@167	351 @findex dfftw_export_wisdom
cannam@167	352 @findex dfftw_forget_wisdom
cannam@167	353
cannam@167	354
cannam@167	355 So, for example, to import the system-wide wisdom, you would do:
cannam@167	356
cannam@167	357 @example
cannam@167	358 integer isuccess
cannam@167	359 call dfftw_import_system_wisdom(isuccess)
cannam@167	360 @end example
cannam@167	361
cannam@167	362 As usual, the C return value is turned into a first parameter;
cannam@167	363 @code{isuccess} is non-zero on success and zero on failure (e.g. if
cannam@167	364 there is no system wisdom installed).
cannam@167	365
cannam@167	366 If you want to import/export wisdom from/to an arbitrary file or
cannam@167	367 elsewhere, you can employ the generic @code{dfftw_import_wisdom} and
cannam@167	368 @code{dfftw_export_wisdom} functions, for which you must supply a
cannam@167	369 subroutine to read/write one character at a time. The FFTW package
cannam@167	370 contains an example file @code{doc/f77_wisdom.f} demonstrating how to
cannam@167	371 implement @code{import_wisdom_from_file} and
cannam@167	372 @code{export_wisdom_to_file} subroutines in this way. (These routines
cannam@167	373 cannot be compiled into the FFTW library itself, lest all FFTW-using
cannam@167	374 programs be required to link with the Fortran I/O library.)

Mercurial > hg > sv-dependency-builds

annotate src/fftw-3.3.8/doc/legacy-fortran.texi @ 169:223a55898ab9 tip default