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282 lines
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282 lines
13 KiB
Text
@node Multi-threaded FFTW, Distributed-memory FFTW with MPI, FFTW Reference, Top
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@chapter Multi-threaded FFTW
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@cindex parallel transform
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In this chapter we document the parallel FFTW routines for
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shared-memory parallel hardware. These routines, which support
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parallel one- and multi-dimensional transforms of both real and
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complex data, are the easiest way to take advantage of multiple
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processors with FFTW. They work just like the corresponding
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uniprocessor transform routines, except that you have an extra
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initialization routine to call, and there is a routine to set the
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number of threads to employ. Any program that uses the uniprocessor
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FFTW can therefore be trivially modified to use the multi-threaded
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FFTW.
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A shared-memory machine is one in which all CPUs can directly access
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the same main memory, and such machines are now common due to the
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ubiquity of multi-core CPUs. FFTW's multi-threading support allows
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you to utilize these additional CPUs transparently from a single
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program. However, this does not necessarily translate into
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performance gains---when multiple threads/CPUs are employed, there is
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an overhead required for synchronization that may outweigh the
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computatational parallelism. Therefore, you can only benefit from
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threads if your problem is sufficiently large.
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@cindex shared-memory
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@cindex threads
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@menu
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* Installation and Supported Hardware/Software::
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* Usage of Multi-threaded FFTW::
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* How Many Threads to Use?::
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* Thread safety::
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@end menu
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@c ------------------------------------------------------------
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@node Installation and Supported Hardware/Software, Usage of Multi-threaded FFTW, Multi-threaded FFTW, Multi-threaded FFTW
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@section Installation and Supported Hardware/Software
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All of the FFTW threads code is located in the @code{threads}
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subdirectory of the FFTW package. On Unix systems, the FFTW threads
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libraries and header files can be automatically configured, compiled,
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and installed along with the uniprocessor FFTW libraries simply by
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including @code{--enable-threads} in the flags to the @code{configure}
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script (@pxref{Installation on Unix}), or @code{--enable-openmp} to use
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@uref{http://www.openmp.org,OpenMP} threads.
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@fpindex configure
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@cindex portability
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@cindex OpenMP
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The threads routines require your operating system to have some sort
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of shared-memory threads support. Specifically, the FFTW threads
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package works with POSIX threads (available on most Unix variants,
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from GNU/Linux to MacOS X) and Win32 threads. OpenMP threads, which
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are supported in many common compilers (e.g. gcc) are also supported,
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and may give better performance on some systems. (OpenMP threads are
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also useful if you are employing OpenMP in your own code, in order to
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minimize conflicts between threading models.) If you have a
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shared-memory machine that uses a different threads API, it should be
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a simple matter of programming to include support for it; see the file
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@code{threads/threads.c} for more detail.
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You can compile FFTW with @emph{both} @code{--enable-threads} and
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@code{--enable-openmp} at the same time, since they install libraries
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with different names (@samp{fftw3_threads} and @samp{fftw3_omp}, as
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described below). However, your programs may only link to @emph{one}
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of these two libraries at a time.
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Ideally, of course, you should also have multiple processors in order to
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get any benefit from the threaded transforms.
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@c ------------------------------------------------------------
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@node Usage of Multi-threaded FFTW, How Many Threads to Use?, Installation and Supported Hardware/Software, Multi-threaded FFTW
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@section Usage of Multi-threaded FFTW
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Here, it is assumed that the reader is already familiar with the usage
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of the uniprocessor FFTW routines, described elsewhere in this manual.
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We only describe what one has to change in order to use the
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multi-threaded routines.
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@cindex OpenMP
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First, programs using the parallel complex transforms should be linked
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with @code{-lfftw3_threads -lfftw3 -lm} on Unix, or @code{-lfftw3_omp
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-lfftw3 -lm} if you compiled with OpenMP. You will also need to link
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with whatever library is responsible for threads on your system
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(e.g. @code{-lpthread} on GNU/Linux) or include whatever compiler flag
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enables OpenMP (e.g. @code{-fopenmp} with gcc).
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@cindex linking on Unix
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Second, before calling @emph{any} FFTW routines, you should call the
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function:
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@example
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int fftw_init_threads(void);
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@end example
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@findex fftw_init_threads
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This function, which need only be called once, performs any one-time
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initialization required to use threads on your system. It returns zero
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if there was some error (which should not happen under normal
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circumstances) and a non-zero value otherwise.
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Third, before creating a plan that you want to parallelize, you should
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call:
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@example
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void fftw_plan_with_nthreads(int nthreads);
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@end example
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@findex fftw_plan_with_nthreads
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The @code{nthreads} argument indicates the number of threads you want
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FFTW to use (or actually, the maximum number). All plans subsequently
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created with any planner routine will use that many threads. You can
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call @code{fftw_plan_with_nthreads}, create some plans, call
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@code{fftw_plan_with_nthreads} again with a different argument, and
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create some more plans for a new number of threads. Plans already created
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before a call to @code{fftw_plan_with_nthreads} are unaffected. If you
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pass an @code{nthreads} argument of @code{1} (the default), threads are
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disabled for subsequent plans.
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You can determine the current number of threads that the planner can
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use by calling:
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@example
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int fftw_planner_nthreads(void);
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@end example
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@findex fftw_planner_nthreads
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@cindex OpenMP
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With OpenMP, to configure FFTW to use all of the currently running
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OpenMP threads (set by @code{omp_set_num_threads(nthreads)} or by the
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@code{OMP_NUM_THREADS} environment variable), you can do:
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@code{fftw_plan_with_nthreads(omp_get_max_threads())}. (The @samp{omp_}
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OpenMP functions are declared via @code{#include <omp.h>}.)
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@cindex thread safety
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Given a plan, you then execute it as usual with
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@code{fftw_execute(plan)}, and the execution will use the number of
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threads specified when the plan was created. When done, you destroy
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it as usual with @code{fftw_destroy_plan}. As described in
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@ref{Thread safety}, plan @emph{execution} is thread-safe, but plan
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creation and destruction are @emph{not}: you should create/destroy
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plans only from a single thread, but can safely execute multiple plans
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in parallel.
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There is one additional routine: if you want to get rid of all memory
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and other resources allocated internally by FFTW, you can call:
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@example
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void fftw_cleanup_threads(void);
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@end example
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@findex fftw_cleanup_threads
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which is much like the @code{fftw_cleanup()} function except that it
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also gets rid of threads-related data. You must @emph{not} execute any
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previously created plans after calling this function.
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We should also mention one other restriction: if you save wisdom from a
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program using the multi-threaded FFTW, that wisdom @emph{cannot be used}
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by a program using only the single-threaded FFTW (i.e. not calling
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@code{fftw_init_threads}). @xref{Words of Wisdom-Saving Plans}.
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Finally, FFTW provides a optional callback interface that allows you to
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replace its parallel threading backend at runtime:
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@example
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void fftw_threads_set_callback(
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void (*parallel_loop)(void *(*work)(void *), char *jobdata, size_t elsize, int njobs, void *data),
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void *data);
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@end example
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@findex fftw_threads_set_callback
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This routine (which is @emph{not} threadsafe and should generally be called before creating
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any FFTW plans) allows you to provide a function @code{parallel_loop} that executes
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parallel work for FFTW: it should call the function @code{work(jobdata + elsize*i)} for
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@code{i} from @code{0} to @code{njobs-1}, possibly in parallel. (The `data` pointer
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supplied to @code{fftw_threads_set_callback} is passed through to your @code{parallel_loop}
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function.) For example, if you link to an FFTW threads library built to use POSIX threads,
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but you want it to use OpenMP instead (because you are using OpenMP elsewhere in your program
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and want to avoid competing threads), you can call @code{fftw_threads_set_callback} with
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the callback function:
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@example
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void parallel_loop(void *(*work)(char *), char *jobdata, size_t elsize, int njobs, void *data)
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@{
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#pragma omp parallel for
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for (int i = 0; i < njobs; ++i)
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work(jobdata + elsize * i);
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@}
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@end example
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The same mechanism could be used in order to make FFTW use a threading backend
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implemented via Intel TBB, Apple GCD, or Cilk, for example.
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@c ------------------------------------------------------------
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@node How Many Threads to Use?, Thread safety, Usage of Multi-threaded FFTW, Multi-threaded FFTW
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@section How Many Threads to Use?
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@cindex number of threads
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There is a fair amount of overhead involved in synchronizing threads,
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so the optimal number of threads to use depends upon the size of the
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transform as well as on the number of processors you have.
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As a general rule, you don't want to use more threads than you have
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processors. (Using more threads will work, but there will be extra
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overhead with no benefit.) In fact, if the problem size is too small,
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you may want to use fewer threads than you have processors.
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You will have to experiment with your system to see what level of
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parallelization is best for your problem size. Typically, the problem
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will have to involve at least a few thousand data points before threads
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become beneficial. If you plan with @code{FFTW_PATIENT}, it will
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automatically disable threads for sizes that don't benefit from
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parallelization.
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@ctindex FFTW_PATIENT
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@c ------------------------------------------------------------
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@node Thread safety, , How Many Threads to Use?, Multi-threaded FFTW
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@section Thread safety
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@cindex threads
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@cindex OpenMP
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@cindex thread safety
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Users writing multi-threaded programs (including OpenMP) must concern
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themselves with the @dfn{thread safety} of the libraries they
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use---that is, whether it is safe to call routines in parallel from
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multiple threads. FFTW can be used in such an environment, but some
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care must be taken because the planner routines share data
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(e.g. wisdom and trigonometric tables) between calls and plans.
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The upshot is that the only thread-safe routine in FFTW is
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@code{fftw_execute} (and the new-array variants thereof). All other routines
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(e.g. the planner) should only be called from one thread at a time. So,
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for example, you can wrap a semaphore lock around any calls to the
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planner; even more simply, you can just create all of your plans from
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one thread. We do not think this should be an important restriction
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(FFTW is designed for the situation where the only performance-sensitive
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code is the actual execution of the transform), and the benefits of
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shared data between plans are great.
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Note also that, since the plan is not modified by @code{fftw_execute},
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it is safe to execute the @emph{same plan} in parallel by multiple
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threads. However, since a given plan operates by default on a fixed
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array, you need to use one of the new-array execute functions (@pxref{New-array Execute Functions}) so that different threads compute the transform of different data.
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(Users should note that these comments only apply to programs using
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shared-memory threads or OpenMP. Parallelism using MPI or forked processes
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involves a separate address-space and global variables for each process,
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and is not susceptible to problems of this sort.)
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The FFTW planner is intended to be called from a single thread. If you
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really must call it from multiple threads, you are expected to grab
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whatever lock makes sense for your application, with the understanding
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that you may be holding that lock for a long time, which is undesirable.
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Neither strategy works, however, in the following situation. The
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``application'' is structured as a set of ``plugins'' which are unaware
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of each other, and for whatever reason the ``plugins'' cannot coordinate
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on grabbing the lock. (This is not a technical problem, but an
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organizational one. The ``plugins'' are written by independent agents,
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and from the perspective of each plugin's author, each plugin is using
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FFTW correctly from a single thread.) To cope with this situation,
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starting from FFTW-3.3.5, FFTW supports an API to make the planner
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thread-safe:
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@example
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void fftw_make_planner_thread_safe(void);
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@end example
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@findex fftw_make_planner_thread_safe
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This call operates by brute force: It just installs a hook that wraps a
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lock (chosen by us) around all planner calls. So there is no magic and
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you get the worst of all worlds. The planner is still single-threaded,
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but you cannot choose which lock to use. The planner still holds the
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lock for a long time, but you cannot impose a timeout on lock
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acquisition. As of FFTW-3.3.5 and FFTW-3.3.6, this call does not work
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when using OpenMP as threading substrate. (Suggestions on what to do
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about this bug are welcome.) @emph{Do not use
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@code{fftw_make_planner_thread_safe} unless there is no other choice,}
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such as in the application/plugin situation.
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