/*! \file pifft.h
* \ingroup Math
* \ingroup FFTW
* \~\brief
* \~english FFT, IFFT and Hilbert transformations
* \~russian БПФ, ОБПФ и преобразования Гильберта
*/
/*
PIP - Platform Independent Primitives
Class for FFT, IFFT and Hilbert transformations
Andrey Bychkov work.a.b@yandex.ru, Ivan Pelipenko peri4ko@yandex.ru
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as published by
the Free Software Foundation, either version 3 of the License, or
(at your option) any later version.
This program 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 Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public License
along with this program. If not, see .
*/
//! \defgroup FFTW FFTW
//! \~\brief
//! \~english Optimized FFT support via libfftw3
//! \~russian Оптимизированный БПФ с помощью libfftw3
//!
//! \~\details
//! \~english \section cmake_module_FFTW Building with CMake
//! \~russian \section cmake_module_FFTW Сборка с использованием CMake
//!
//! \~\code
//! find_package(PIP REQUIRED)
//! target_link_libraries([target] PIP::FFTW)
//! \endcode
//!
//! \~english \par Common
//! \~russian \par Общее
//!
//! \~english
//! These files provides FFT using [libfftw3](https://fftw.org/)
//!
//! \~russian
//! Эти файлы обеспечивают БПФ с использованием [libfftw3](https://fftw.org/)
//!
//! \~\authors
//! \~english
//! Ivan Pelipenko peri4ko@yandex.ru;
//! Andrey Bychkov work.a.b@yandex.ru;
//! \~russian
//! Иван Пелипенко peri4ko@yandex.ru;
//! Андрей Бычков work.a.b@yandex.ru;
//!
#ifndef PIFFT_H
#define PIFFT_H
#include "pimathcomplex.h"
#ifndef MICRO_PIP
# include "pip_fftw_export.h"
class PIP_EXPORT PIFFT_double {
public:
PIFFT_double();
PIVector * calcFFT(const PIVector & val);
PIVector * calcFFT(const PIVector & val);
PIVector * calcFFTinverse(const PIVector & val);
PIVector * calcHilbert(const PIVector & val);
PIVector getAmplitude() const;
PIVector getReal() const;
PIVector getImag() const;
private:
PIVector result;
typedef ptrdiff_t ae_int_t;
struct ftplan {
PIVector plan;
PIVector precomputed;
PIVector tmpbuf;
PIVector stackbuf;
};
ftplan curplan;
void fftc1d(const PIVector & a, uint n);
void fftc1r(const PIVector & a, uint n);
void fftc1dinv(const PIVector & a, uint n);
void createPlan(uint n);
void ftbasegeneratecomplexfftplan(uint n, ftplan * plan);
void ftbase_ftbasegenerateplanrec(int n,
int tasktype,
ftplan * plan,
int * plansize,
int * precomputedsize,
int * planarraysize,
int * tmpmemsize,
int * stackmemsize,
ae_int_t stackptr,
int debugi = 0);
void ftbase_ftbaseprecomputeplanrec(ftplan * plan, int entryoffset, ae_int_t stackptr);
void ftbasefactorize(int n, int * n1, int * n2);
void ftbase_ftbasefindsmoothrec(int n, int seed, int leastfactor, int * best);
int ftbasefindsmooth(int n);
void ftbaseexecuteplan(PIVector * a, int aoffset, int n, ftplan * plan);
void ftbaseexecuteplanrec(PIVector * a, int aoffset, ftplan * plan, int entryoffset, ae_int_t stackptr);
void ftbase_internalcomplexlintranspose(PIVector * a, int m, int n, int astart, PIVector * buf);
void ftbase_ffticltrec(PIVector * a, int astart, int astride, PIVector * b, int bstart, int bstride, int m, int n);
void ftbase_internalreallintranspose(PIVector * a, int m, int n, int astart, PIVector * buf);
void ftbase_fftirltrec(PIVector * a, int astart, int astride, PIVector * b, int bstart, int bstride, int m, int n);
void ftbase_ffttwcalc(PIVector * a, int aoffset, int n1, int n2);
};
class PIP_EXPORT PIFFT_float {
public:
PIFFT_float();
PIVector * calcFFT(const PIVector & val);
PIVector * calcFFT(const PIVector & val);
PIVector * calcFFTinverse(const PIVector & val);
PIVector * calcHilbert(const PIVector & val);
PIVector getAmplitude() const;
PIVector getReal() const;
PIVector getImag() const;
private:
PIVector result;
typedef ptrdiff_t ae_int_t;
struct ftplan {
PIVector plan;
PIVector precomputed;
PIVector tmpbuf;
PIVector stackbuf;
};
ftplan curplan;
void fftc1d(const PIVector & a, uint n);
void fftc1r(const PIVector & a, uint n);
void fftc1dinv(const PIVector & a, uint n);
void createPlan(uint n);
void ftbasegeneratecomplexfftplan(uint n, ftplan * plan);
void ftbase_ftbasegenerateplanrec(int n,
int tasktype,
ftplan * plan,
int * plansize,
int * precomputedsize,
int * planarraysize,
int * tmpmemsize,
int * stackmemsize,
ae_int_t stackptr,
int debugi = 0);
void ftbase_ftbaseprecomputeplanrec(ftplan * plan, int entryoffset, ae_int_t stackptr);
void ftbasefactorize(int n, int * n1, int * n2);
void ftbase_ftbasefindsmoothrec(int n, int seed, int leastfactor, int * best);
int ftbasefindsmooth(int n);
void ftbaseexecuteplan(PIVector * a, int aoffset, int n, ftplan * plan);
void ftbaseexecuteplanrec(PIVector * a, int aoffset, ftplan * plan, int entryoffset, ae_int_t stackptr);
void ftbase_internalcomplexlintranspose(PIVector * a, int m, int n, int astart, PIVector * buf);
void ftbase_ffticltrec(PIVector * a, int astart, int astride, PIVector * b, int bstart, int bstride, int m, int n);
void ftbase_internalreallintranspose(PIVector * a, int m, int n, int astart, PIVector * buf);
void ftbase_fftirltrec(PIVector * a, int astart, int astride, PIVector * b, int bstart, int bstride, int m, int n);
void ftbase_ffttwcalc(PIVector * a, int aoffset, int n1, int n2);
};
typedef PIFFT_double PIFFT;
typedef PIFFT_double PIFFTd;
typedef PIFFT_float PIFFTf;
# ifndef CC_VC
# define _PIFFTW_H(type) \
class PIP_FFTW_EXPORT _PIFFTW_P_##type##_ { \
public: \
_PIFFTW_P_##type##_(); \
~_PIFFTW_P_##type##_(); \
const PIVector> & calcFFT(const PIVector> & in); \
const PIVector> & calcFFTR(const PIVector & in); \
const PIVector> & calcFFTI(const PIVector> & in); \
void preparePlan(int size, int op); \
void * impl; \
};
_PIFFTW_H(float)
_PIFFTW_H(double)
_PIFFTW_H(ldouble)
template
class PIFFTW {
public:
explicit PIFFTW() {
p = 0;
newP(p);
}
~PIFFTW() { deleteP(p); }
inline const PIVector> & calcFFT(const PIVector> & in) { return PIVector>().resize(in.size()); }
inline const PIVector> & calcFFT(const PIVector & in) { return PIVector>().resize(in.size()); }
inline const PIVector> & calcFFTinverse(const PIVector> & in) { return PIVector>().resize(in.size()); }
enum FFT_Operation {
foReal,
foComplex,
foInverse
};
inline void preparePlan(int size, FFT_Operation op) {}
private:
void operator=(const PIFFTW &);
PIFFTW(const PIFFTW &);
inline void newP(void *& _p) {}
inline void deleteP(void *& _p) {}
void * p;
};
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector> & in) {
return ((_PIFFTW_P_float_ *)p)->calcFFT(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector & in) {
return ((_PIFFTW_P_float_ *)p)->calcFFTR(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFTinverse(const PIVector> & in) {
return ((_PIFFTW_P_float_ *)p)->calcFFTI(in);
}
template<>
inline void PIFFTW::preparePlan(int size, FFT_Operation op) {
((_PIFFTW_P_float_ *)p)->preparePlan(size, op);
}
template<>
inline void PIFFTW::newP(void *& _p) {
_p = new _PIFFTW_P_float_();
}
template<>
inline void PIFFTW::deleteP(void *& _p) {
if (_p) delete (_PIFFTW_P_float_ *)_p;
_p = 0;
}
typedef PIFFTW PIFFTWf;
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector> & in) {
return ((_PIFFTW_P_double_ *)p)->calcFFT(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector & in) {
return ((_PIFFTW_P_double_ *)p)->calcFFTR(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFTinverse(const PIVector> & in) {
return ((_PIFFTW_P_double_ *)p)->calcFFTI(in);
}
template<>
inline void PIFFTW::preparePlan(int size, FFT_Operation op) {
((_PIFFTW_P_double_ *)p)->preparePlan(size, op);
}
template<>
inline void PIFFTW::newP(void *& _p) {
_p = new _PIFFTW_P_double_();
}
template<>
inline void PIFFTW::deleteP(void *& _p) {
if (_p) delete (_PIFFTW_P_double_ *)_p;
_p = 0;
}
typedef PIFFTW PIFFTWd;
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector> & in) {
return ((_PIFFTW_P_ldouble_ *)p)->calcFFT(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFT(const PIVector & in) {
return ((_PIFFTW_P_ldouble_ *)p)->calcFFTR(in);
}
template<>
inline const PIVector> & PIFFTW::calcFFTinverse(const PIVector> & in) {
return ((_PIFFTW_P_ldouble_ *)p)->calcFFTI(in);
}
template<>
inline void PIFFTW::preparePlan(int size, FFT_Operation op) {
((_PIFFTW_P_ldouble_ *)p)->preparePlan(size, op);
}
template<>
inline void PIFFTW::newP(void *& _p) {
_p = new _PIFFTW_P_ldouble_();
}
template<>
inline void PIFFTW::deleteP(void *& _p) {
if (_p) delete (_PIFFTW_P_ldouble_ *)_p;
_p = 0;
}
typedef PIFFTW PIFFTWld;
# endif
#endif // MICRO_PIP
#endif // PIFFT_H