// @(#)root/fft:$Id$ // Author: Anna Kreshuk 07/4/2006 /************************************************************************* * Copyright (C) 1995-2006, Rene Brun and Fons Rademakers. * * All rights reserved. * * * * For the licensing terms see $ROOTSYS/LICENSE. * * For the list of contributors see $ROOTSYS/README/CREDITS. * *************************************************************************/ #ifndef ROOT_TFFTComplexReal #define ROOT_TFFTComplexReal ////////////////////////////////////////////////////////////////////////// // // TFFTComplexReal // // One of the interface classes to the FFTW package, can be used directly // or via the TVirtualFFT class. Only the basic interface of FFTW is implemented. // // Computes the inverse of the real-to-complex transforms (class TFFTRealComplex) // taking complex input (storing the non-redundant half of a logically Hermitian array) // to real output (see FFTW manual for more details) // // How to use it: // 1) Create an instance of TFFTComplexReal - this will allocate input and output // arrays (unless an in-place transform is specified) // 2) Run the Init() function with the desired flags and settings // 3) Set the data (via SetPoints(), SetPoint() or SetPointComplex() functions) // 4) Run the Transform() function // 5) Get the output (via GetPoints(), GetPoint() or GetPointReal() functions) // 6) Repeat steps 3)-5) as needed // // For a transform of the same size, but with different flags, rerun the Init() // function and continue with steps 3)-5) // NOTE: 1) running Init() function will overwrite the input array! Don't set any data // before running the Init() function // 2) FFTW computes unnormalized transform, so doing a transform followed by // its inverse will lead to the original array scaled by the transform size // ////////////////////////////////////////////////////////////////////////// #ifndef ROOT_TVirtualFFT #include "TVirtualFFT.h" #endif class TComplex; class TFFTComplexReal: public TVirtualFFT { protected: void *fIn; //input array void *fOut; //output array void *fPlan; //fftw plan (the plan how to compute the transform) Int_t fNdim; //number of dimensions Int_t fTotalSize; //total size of the transform Int_t *fN; //transform sizes in each dimension Option_t *fFlags; //transform flags UInt_t MapFlag(Option_t *flag); public: TFFTComplexReal(); TFFTComplexReal(Int_t n, Bool_t inPlace); TFFTComplexReal(Int_t ndim, Int_t *n, Bool_t inPlace); virtual ~TFFTComplexReal(); virtual void Init( Option_t *flags, Int_t /*sign*/,const Int_t* /*kind*/); virtual Int_t GetSize() const {return fTotalSize;} virtual Int_t *GetN() const {return fN;} virtual Int_t GetNdim() const {return fNdim;} virtual Option_t *GetType() const {return "C2R";} virtual Int_t GetSign() const {return -1;} virtual Option_t *GetTransformFlag() const {return fFlags;} virtual Bool_t IsInplace() const {if (fOut) return kTRUE; else return kFALSE;}; virtual void GetPoints(Double_t *data, Bool_t fromInput = kFALSE) const; virtual Double_t GetPointReal(Int_t ipoint, Bool_t fromInput = kFALSE) const; virtual Double_t GetPointReal(const Int_t *ipoint, Bool_t fromInput = kFALSE) const; virtual void GetPointComplex(Int_t ipoint, Double_t &re, Double_t &im, Bool_t fromInput=kFALSE) const; virtual void GetPointComplex(const Int_t *ipoint, Double_t &re, Double_t &im, Bool_t fromInput=kFALSE) const; virtual Double_t* GetPointsReal(Bool_t fromInput=kFALSE) const; virtual void GetPointsComplex(Double_t *re, Double_t *im, Bool_t fromInput = kFALSE) const ; virtual void GetPointsComplex(Double_t *data, Bool_t fromInput = kFALSE) const ; virtual void SetPoint(Int_t ipoint, Double_t re, Double_t im = 0); virtual void SetPoint(const Int_t *ipoint, Double_t re, Double_t im = 0); virtual void SetPoints(const Double_t *data); virtual void SetPointComplex(Int_t ipoint, TComplex &c); virtual void SetPointsComplex(const Double_t *re, const Double_t *im); virtual void Transform(); ClassDef(TFFTComplexReal,0); }; #endif