/* -*- c++ -*- */ /* * Copyright 2003,2008,2012 Free Software Foundation, Inc. * * This file is part of GNU Radio * * GNU Radio is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3, or (at your option) * any later version. * * GNU Radio is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with GNU Radio; see the file COPYING. If not, write to * the Free Software Foundation, Inc., 51 Franklin Street, * Boston, MA 02110-1301, USA. */ #ifndef _FFT_FFT_H_ #define _FFT_FFT_H_ /* * Wrappers for FFTW single precision 1d dft */ #include #include #include namespace gr { namespace fft { /*! \brief Helper function for allocating complex fft buffers */ FFT_API gr_complex* malloc_complex(int size); /*! \brief Helper function for allocating float fft buffers */ FFT_API float* malloc_float(int size); /*! \brief Helper function for freeing fft buffers */ FFT_API void free(void *b); /*! * \brief Export reference to planner mutex for those apps that * want to use FFTW w/o using the fft_impl_fftw* classes. */ class FFT_API planner { public: typedef boost::mutex::scoped_lock scoped_lock; /*! * Return reference to planner mutex */ static boost::mutex &mutex(); }; /*! * \brief FFT: complex in, complex out * \ingroup misc */ class FFT_API fft_complex { int d_fft_size; int d_nthreads; gr_complex *d_inbuf; gr_complex *d_outbuf; void *d_plan; public: fft_complex(int fft_size, bool forward = true, int nthreads=1); virtual ~fft_complex(); /* * These return pointers to buffers owned by fft_impl_fft_complex * into which input and output take place. It's done this way in * order to ensure optimal alignment for SIMD instructions. */ gr_complex *get_inbuf() const { return d_inbuf; } gr_complex *get_outbuf() const { return d_outbuf; } int inbuf_length() const { return d_fft_size; } int outbuf_length() const { return d_fft_size; } /*! * Set the number of threads to use for caclulation. */ void set_nthreads(int n); /*! * Get the number of threads being used by FFTW */ int nthreads() const { return d_nthreads; } /*! * compute FFT. The input comes from inbuf, the output is placed in * outbuf. */ void execute(); }; /*! * \brief FFT: real in, complex out * \ingroup misc */ class FFT_API fft_real_fwd { int d_fft_size; int d_nthreads; float *d_inbuf; gr_complex *d_outbuf; void *d_plan; public: fft_real_fwd (int fft_size, int nthreads=1); virtual ~fft_real_fwd (); /* * These return pointers to buffers owned by fft_impl_fft_real_fwd * into which input and output take place. It's done this way in * order to ensure optimal alignment for SIMD instructions. */ float *get_inbuf() const { return d_inbuf; } gr_complex *get_outbuf() const { return d_outbuf; } int inbuf_length() const { return d_fft_size; } int outbuf_length() const { return d_fft_size / 2 + 1; } /*! * Set the number of threads to use for caclulation. */ void set_nthreads(int n); /*! * Get the number of threads being used by FFTW */ int nthreads() const { return d_nthreads; } /*! * compute FFT. The input comes from inbuf, the output is placed in * outbuf. */ void execute(); }; /*! * \brief FFT: complex in, float out * \ingroup misc */ class FFT_API fft_real_rev { int d_fft_size; int d_nthreads; gr_complex *d_inbuf; float *d_outbuf; void *d_plan; public: fft_real_rev(int fft_size, int nthreads=1); virtual ~fft_real_rev(); /* * These return pointers to buffers owned by fft_impl_fft_real_rev * into which input and output take place. It's done this way in * order to ensure optimal alignment for SIMD instructions. */ gr_complex *get_inbuf() const { return d_inbuf; } float *get_outbuf() const { return d_outbuf; } int inbuf_length() const { return d_fft_size / 2 + 1; } int outbuf_length() const { return d_fft_size; } /*! * Set the number of threads to use for caclulation. */ void set_nthreads(int n); /*! * Get the number of threads being used by FFTW */ int nthreads() const { return d_nthreads; } /*! * compute FFT. The input comes from inbuf, the output is placed in * outbuf. */ void execute(); }; } /* namespace fft */ } /*namespace gr */ #endif /* _FFT_FFT_H_ */