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820 lines
18 KiB
C++
Vendored
820 lines
18 KiB
C++
Vendored
//$ nobt
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//$ nocpp
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/**
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* @file CDSPRealFFT.h
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*
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* @brief Real-valued FFT transform class.
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*
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* This file includes FFT object implementation. All created FFT objects are
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* kept in a global list after use, for a future reusal. Such approach
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* minimizes time necessary to initialize the FFT object of the required
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* length.
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*
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* r8brain-free-src Copyright (c) 2013-2022 Aleksey Vaneev
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* See the "LICENSE" file for license.
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*/
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#ifndef R8B_CDSPREALFFT_INCLUDED
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#define R8B_CDSPREALFFT_INCLUDED
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#include "r8bbase.h"
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#if !R8B_IPP && !R8B_PFFFT && !R8B_PFFFT_DOUBLE
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#include "fft4g.h"
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#endif // !R8B_IPP && !R8B_PFFFT && !R8B_PFFFT_DOUBLE
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#if R8B_PFFFT
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#include "pffft.h"
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#endif // R8B_PFFFT
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#if R8B_PFFFT_DOUBLE
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#include "pffft_double/pffft_double.h"
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#endif // R8B_PFFFT_DOUBLE
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namespace r8b {
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/**
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* @brief Real-valued FFT transform class.
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*
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* Class implements a wrapper for real-valued discrete fast Fourier transform
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* functions. The object of this class can only be obtained via the
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* CDSPRealFFTKeeper class.
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*
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* Uses functions from the FFT package by: Copyright(C) 1996-2001 Takuya OOURA
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* http://www.kurims.kyoto-u.ac.jp/~ooura/fft.html
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*
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* Also uses Intel IPP library functions if available (if the R8B_IPP=1 macro
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* was defined). Note that IPP library's FFT functions are 2-3 times more
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* efficient on the modern Intel Core i7-3770K processor than Ooura's
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* functions. It may be worthwhile investing in IPP. Note, that FFT functions
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* take less than 20% of the overall sample rate conversion time. However,
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* when the "power of 2" resampling is used the performance of FFT functions
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* becomes "everything".
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*/
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class CDSPRealFFT : public R8B_BASECLASS
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{
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R8BNOCTOR( CDSPRealFFT );
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friend class CDSPRealFFTKeeper;
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public:
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/**
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* @return A multiplication constant that should be used after inverse
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* transform to obtain a correct value scale.
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*/
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double getInvMulConst() const
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{
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return( InvMulConst );
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}
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/**
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* @return The length (the number of real values in a transform) of *this
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* FFT object, expressed as Nth power of 2.
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*/
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int getLenBits() const
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{
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return( LenBits );
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}
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/**
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* @return The length (the number of real values in a transform) of *this
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* FFT object.
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*/
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int getLen() const
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{
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return( Len );
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}
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/**
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* Function performs in-place forward FFT.
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*
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* @param[in,out] p Pointer to data block to transform, length should be
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* equal to *this object's getLen().
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*/
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void forward( double* const p ) const
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{
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#if R8B_FLOATFFT
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float* const op = (float*) p;
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int i;
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for( i = 0; i < Len; i++ )
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{
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op[ i ] = (float) p[ i ];
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}
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#endif // R8B_FLOATFFT
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#if R8B_IPP
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ippsFFTFwd_RToPerm_64f( p, p, SPtr, WorkBuffer );
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#elif R8B_PFFFT
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pffft_transform_ordered( setup, op, op, work, PFFFT_FORWARD );
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#elif R8B_PFFFT_DOUBLE
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pffftd_transform_ordered( setup, p, p, work, PFFFT_FORWARD );
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#else // R8B_PFFFT_DOUBLE
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ooura_fft :: rdft( Len, 1, p, wi.getPtr(), wd.getPtr() );
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#endif // R8B_IPP
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}
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/**
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* Function performs in-place inverse FFT.
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*
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* @param[in,out] p Pointer to data block to transform, length should be
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* equal to *this object's getLen().
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*/
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void inverse( double* const p ) const
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{
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#if R8B_IPP
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ippsFFTInv_PermToR_64f( p, p, SPtr, WorkBuffer );
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#elif R8B_PFFFT
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pffft_transform_ordered( setup, (float*) p, (float*) p, work,
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PFFFT_BACKWARD );
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#elif R8B_PFFFT_DOUBLE
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pffftd_transform_ordered( setup, p, p, work, PFFFT_BACKWARD );
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#else // R8B_PFFFT_DOUBLE
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ooura_fft :: rdft( Len, -1, p, wi.getPtr(), wd.getPtr() );
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#endif // R8B_IPP
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#if R8B_FLOATFFT
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const float* const ip = (const float*) p;
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int i;
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for( i = Len - 1; i >= 0; i-- )
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{
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p[ i ] = ip[ i ];
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}
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#endif // R8B_FLOATFFT
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}
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/**
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* Function multiplies two complex-valued data blocks and places result in
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* a new data block. Length of all data blocks should be equal to *this
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* object's block length. Input blocks should have been produced with the
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* forward() function of *this object.
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*
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* @param aip1 Input data block 1.
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* @param aip2 Input data block 2.
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* @param[out] aop Output data block, should not be equal to aip1 nor
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* aip2.
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*/
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void multiplyBlocks( const double* const aip1, const double* const aip2,
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double* const aop ) const
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{
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#if R8B_FLOATFFT
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const float* const ip1 = (const float*) aip1;
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const float* const ip2 = (const float*) aip2;
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float* const op = (float*) aop;
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#else // R8B_FLOATFFT
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const double* const ip1 = aip1;
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const double* const ip2 = aip2;
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double* const op = aop;
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#endif // R8B_FLOATFFT
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#if R8B_IPP
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ippsMulPerm_64f( (Ipp64f*) ip1, (Ipp64f*) ip2, (Ipp64f*) op, Len );
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#else // R8B_IPP
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op[ 0 ] = ip1[ 0 ] * ip2[ 0 ];
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op[ 1 ] = ip1[ 1 ] * ip2[ 1 ];
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int i = 2;
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while( i < Len )
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{
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op[ i ] = ip1[ i ] * ip2[ i ] - ip1[ i + 1 ] * ip2[ i + 1 ];
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op[ i + 1 ] = ip1[ i ] * ip2[ i + 1 ] + ip1[ i + 1 ] * ip2[ i ];
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i += 2;
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}
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#endif // R8B_IPP
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}
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/**
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* Function multiplies two complex-valued data blocks in-place. Length of
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* both data blocks should be equal to *this object's block length. Blocks
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* should have been produced with the forward() function of *this object.
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*
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* @param aip Input data block 1.
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* @param[in,out] aop Output/input data block 2.
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*/
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void multiplyBlocks( const double* const aip, double* const aop ) const
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{
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#if R8B_FLOATFFT
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const float* const ip = (const float*) aip;
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float* const op = (float*) aop;
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float t;
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#else // R8B_FLOATFFT
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const double* const ip = aip;
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double* const op = aop;
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#if !R8B_IPP
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double t;
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#endif // !R8B_IPP
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#endif // R8B_FLOATFFT
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#if R8B_IPP
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ippsMulPerm_64f( (Ipp64f*) op, (Ipp64f*) ip, (Ipp64f*) op, Len );
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#else // R8B_IPP
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op[ 0 ] *= ip[ 0 ];
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op[ 1 ] *= ip[ 1 ];
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int i = 2;
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while( i < Len )
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{
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t = op[ i ] * ip[ i ] - op[ i + 1 ] * ip[ i + 1 ];
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op[ i + 1 ] = op[ i ] * ip[ i + 1 ] + op[ i + 1 ] * ip[ i ];
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op[ i ] = t;
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i += 2;
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}
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#endif // R8B_IPP
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}
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/**
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* Function multiplies two complex-valued data blocks in-place,
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* considering that the "ip" block contains "zero-phase" response. Length
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* of both data blocks should be equal to *this object's block length.
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* Blocks should have been produced with the forward() function of *this
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* object.
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*
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* @param aip Input data block 1, "zero-phase" response. This block should
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* be first transformed via the convertToZP() function.
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* @param[in,out] aop Output/input data block 2.
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*/
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void multiplyBlocksZP( const double* const aip, double* const aop ) const
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{
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#if R8B_FLOATFFT
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const float* const ip = (const float*) aip;
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float* const op = (float*) aop;
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#else // R8B_FLOATFFT
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const double* ip = aip;
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double* op = aop;
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#endif // R8B_FLOATFFT
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// SIMD implementations assume that pointers are address-aligned.
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#if !R8B_FLOATFFT && defined( R8B_SSE2 )
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int c8 = Len >> 3;
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while( c8 != 0 )
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{
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const __m128d iv1 = _mm_load_pd( ip );
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const __m128d iv2 = _mm_load_pd( ip + 2 );
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const __m128d ov1 = _mm_load_pd( op );
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const __m128d ov2 = _mm_load_pd( op + 2 );
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_mm_store_pd( op, _mm_mul_pd( iv1, ov1 ));
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_mm_store_pd( op + 2, _mm_mul_pd( iv2, ov2 ));
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const __m128d iv3 = _mm_load_pd( ip + 4 );
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const __m128d ov3 = _mm_load_pd( op + 4 );
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const __m128d iv4 = _mm_load_pd( ip + 6 );
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const __m128d ov4 = _mm_load_pd( op + 6 );
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_mm_store_pd( op + 4, _mm_mul_pd( iv3, ov3 ));
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_mm_store_pd( op + 6, _mm_mul_pd( iv4, ov4 ));
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ip += 8;
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op += 8;
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c8--;
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}
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int c = Len & 7;
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while( c != 0 )
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{
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*op *= *ip;
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ip++;
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op++;
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c--;
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}
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#elif !R8B_FLOATFFT && defined( R8B_NEON )
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int c8 = Len >> 3;
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while( c8 != 0 )
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{
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const float64x2_t iv1 = vld1q_f64( ip );
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const float64x2_t iv2 = vld1q_f64( ip + 2 );
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const float64x2_t ov1 = vld1q_f64( op );
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const float64x2_t ov2 = vld1q_f64( op + 2 );
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vst1q_f64( op, vmulq_f64( iv1, ov1 ));
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vst1q_f64( op + 2, vmulq_f64( iv2, ov2 ));
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const float64x2_t iv3 = vld1q_f64( ip + 4 );
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const float64x2_t iv4 = vld1q_f64( ip + 6 );
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const float64x2_t ov3 = vld1q_f64( op + 4 );
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const float64x2_t ov4 = vld1q_f64( op + 6 );
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vst1q_f64( op + 4, vmulq_f64( iv3, ov3 ));
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vst1q_f64( op + 6, vmulq_f64( iv4, ov4 ));
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ip += 8;
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op += 8;
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c8--;
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}
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int c = Len & 7;
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while( c != 0 )
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{
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*op *= *ip;
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ip++;
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op++;
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c--;
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}
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#else // SIMD
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int i;
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for( i = 0; i < Len; i++ )
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{
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op[ i ] *= ip[ i ];
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}
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#endif // SIMD
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}
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/**
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* Function converts the specified forward-transformed block into
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* "zero-phase" form suitable for use with the multiplyBlocksZ() function.
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*
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* @param[in,out] ap Block to transform.
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*/
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void convertToZP( double* const ap ) const
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{
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#if R8B_FLOATFFT
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float* const p = (float*) ap;
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#else // R8B_FLOATFFT
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double* const p = ap;
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#endif // R8B_FLOATFFT
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int i = 2;
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while( i < Len )
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{
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p[ i + 1 ] = p[ i ];
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i += 2;
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}
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}
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private:
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int LenBits; ///< Length of FFT block (expressed as Nth power of 2).
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///<
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int Len; ///< Length of FFT block (number of real values).
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///<
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double InvMulConst; ///< Inverse FFT multiply constant.
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///<
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CDSPRealFFT* Next; ///< Next object in a singly-linked list.
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///<
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#if R8B_IPP
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IppsFFTSpec_R_64f* SPtr; ///< Pointer to initialized data buffer
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///< to be passed to IPP's FFT functions.
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///<
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CFixedBuffer< unsigned char > SpecBuffer; ///< Working buffer.
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///<
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CFixedBuffer< unsigned char > WorkBuffer; ///< Working buffer.
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///<
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#elif R8B_PFFFT
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PFFFT_Setup* setup; ///< PFFFT setup object.
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///<
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CFixedBuffer< float > work; ///< Working buffer.
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///<
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#elif R8B_PFFFT_DOUBLE
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PFFFTD_Setup* setup; ///< PFFFTD setup object.
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///<
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CFixedBuffer< double > work; ///< Working buffer.
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///<
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#else // R8B_PFFFT_DOUBLE
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CFixedBuffer< int > wi; ///< Working buffer (ints).
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///<
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CFixedBuffer< double > wd; ///< Working buffer (doubles).
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///<
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#endif // R8B_IPP
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/**
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* A simple class that keeps the pointer to the object and deletes it
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* automatically.
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*/
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class CObjKeeper
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{
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R8BNOCTOR( CObjKeeper );
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public:
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CObjKeeper()
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: Object( NULL )
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{
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}
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~CObjKeeper()
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{
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delete Object;
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}
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CObjKeeper& operator = ( CDSPRealFFT* const aObject )
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{
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Object = aObject;
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return( *this );
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}
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operator CDSPRealFFT* () const
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{
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return( Object );
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}
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private:
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CDSPRealFFT* Object; ///< FFT object being kept.
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///<
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};
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CDSPRealFFT()
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{
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}
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/**
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* Constructor initializes FFT object.
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*
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* @param aLenBits The length of FFT block (Nth power of 2), specifies the
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* number of real values in a block. Values from 1 to 30 inclusive are
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* supported.
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*/
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CDSPRealFFT( const int aLenBits )
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: LenBits( aLenBits )
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, Len( 1 << aLenBits )
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#if R8B_IPP
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, InvMulConst( 1.0 / Len )
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#elif R8B_PFFFT
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, InvMulConst( 1.0 / Len )
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#elif R8B_PFFFT_DOUBLE
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, InvMulConst( 1.0 / Len )
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#else // R8B_PFFFT_DOUBLE
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, InvMulConst( 2.0 / Len )
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#endif // R8B_IPP
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{
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#if R8B_IPP
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int SpecSize;
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int SpecBufferSize;
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int BufferSize;
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ippsFFTGetSize_R_64f( LenBits, IPP_FFT_NODIV_BY_ANY,
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ippAlgHintFast, &SpecSize, &SpecBufferSize, &BufferSize );
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CFixedBuffer< unsigned char > InitBuffer( SpecBufferSize );
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SpecBuffer.alloc( SpecSize );
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WorkBuffer.alloc( BufferSize );
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ippsFFTInit_R_64f( &SPtr, LenBits, IPP_FFT_NODIV_BY_ANY,
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ippAlgHintFast, SpecBuffer, InitBuffer );
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#elif R8B_PFFFT
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setup = pffft_new_setup( Len, PFFFT_REAL );
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work.alloc( Len );
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#elif R8B_PFFFT_DOUBLE
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setup = pffftd_new_setup( Len, PFFFT_REAL );
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work.alloc( Len );
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#else // R8B_PFFFT_DOUBLE
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wi.alloc( (int) ceil( 2.0 + sqrt( (double) ( Len >> 1 ))));
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wi[ 0 ] = 0;
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wd.alloc( Len >> 1 );
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#endif // R8B_IPP
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}
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~CDSPRealFFT()
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{
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#if R8B_PFFFT
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pffft_destroy_setup( setup );
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#elif R8B_PFFFT_DOUBLE
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pffftd_destroy_setup( setup );
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#endif // R8B_PFFFT_DOUBLE
|
|
|
|
delete Next;
|
|
}
|
|
};
|
|
|
|
/**
|
|
* @brief A "keeper" class for real-valued FFT transform objects.
|
|
*
|
|
* Class implements "keeper" functionality for handling CDSPRealFFT objects.
|
|
* The allocated FFT objects are placed on the global static list of objects
|
|
* for future reuse instead of deallocation.
|
|
*/
|
|
|
|
class CDSPRealFFTKeeper : public R8B_BASECLASS
|
|
{
|
|
R8BNOCTOR( CDSPRealFFTKeeper );
|
|
|
|
public:
|
|
CDSPRealFFTKeeper()
|
|
: Object( NULL )
|
|
{
|
|
}
|
|
|
|
/**
|
|
* Function acquires FFT object with the specified block length.
|
|
*
|
|
* @param LenBits The length of FFT block (Nth power of 2), in the range
|
|
* [1; 30] inclusive, specifies the number of real values in a FFT block.
|
|
*/
|
|
|
|
CDSPRealFFTKeeper( const int LenBits )
|
|
{
|
|
Object = acquire( LenBits );
|
|
}
|
|
|
|
~CDSPRealFFTKeeper()
|
|
{
|
|
if( Object != NULL )
|
|
{
|
|
release( Object );
|
|
}
|
|
}
|
|
|
|
/**
|
|
* @return Pointer to the acquired FFT object.
|
|
*/
|
|
|
|
const CDSPRealFFT* operator -> () const
|
|
{
|
|
R8BASSERT( Object != NULL );
|
|
|
|
return( Object );
|
|
}
|
|
|
|
/**
|
|
* Function acquires FFT object with the specified block length. This
|
|
* function can be called any number of times.
|
|
*
|
|
* @param LenBits The length of FFT block (Nth power of 2), in the range
|
|
* [1; 30] inclusive, specifies the number of real values in a FFT block.
|
|
*/
|
|
|
|
void init( const int LenBits )
|
|
{
|
|
if( Object != NULL )
|
|
{
|
|
if( Object -> LenBits == LenBits )
|
|
{
|
|
return;
|
|
}
|
|
|
|
release( Object );
|
|
}
|
|
|
|
Object = acquire( LenBits );
|
|
}
|
|
|
|
/**
|
|
* Function releases a previously acquired FFT object.
|
|
*/
|
|
|
|
void reset()
|
|
{
|
|
if( Object != NULL )
|
|
{
|
|
release( Object );
|
|
Object = NULL;
|
|
}
|
|
}
|
|
|
|
private:
|
|
CDSPRealFFT* Object; ///< FFT object.
|
|
///<
|
|
|
|
static CSyncObject StateSync; ///< FFTObjects synchronizer.
|
|
///<
|
|
static CDSPRealFFT :: CObjKeeper FFTObjects[]; ///< Pool of FFT objects of
|
|
///< various lengths.
|
|
///<
|
|
|
|
/**
|
|
* Function acquires FFT object from the global pool.
|
|
*
|
|
* @param LenBits FFT block length (expressed as Nth power of 2).
|
|
*/
|
|
|
|
CDSPRealFFT* acquire( const int LenBits )
|
|
{
|
|
R8BASSERT( LenBits > 0 && LenBits <= 30 );
|
|
|
|
R8BSYNC( StateSync );
|
|
|
|
if( FFTObjects[ LenBits ] == NULL )
|
|
{
|
|
return( new CDSPRealFFT( LenBits ));
|
|
}
|
|
|
|
CDSPRealFFT* ffto = FFTObjects[ LenBits ];
|
|
FFTObjects[ LenBits ] = ffto -> Next;
|
|
|
|
return( ffto );
|
|
}
|
|
|
|
/**
|
|
* Function releases a previously acquired FFT object.
|
|
*
|
|
* @param ffto FFT object to release.
|
|
*/
|
|
|
|
void release( CDSPRealFFT* const ffto )
|
|
{
|
|
R8BSYNC( StateSync );
|
|
|
|
ffto -> Next = FFTObjects[ ffto -> LenBits ];
|
|
FFTObjects[ ffto -> LenBits ] = ffto;
|
|
}
|
|
};
|
|
|
|
/**
|
|
* Function calculates the minimum-phase transform of the filter kernel, using
|
|
* a discrete Hilbert transform in cepstrum domain.
|
|
*
|
|
* For more details, see part III.B of
|
|
* http://www.hpl.hp.com/personal/Niranjan_Damera-Venkata/files/ComplexMinPhase.pdf
|
|
*
|
|
* @param[in,out] Kernel Filter kernel buffer.
|
|
* @param KernelLen Filter kernel's length, in samples.
|
|
* @param LenMult Kernel length multiplier. Used as a coefficient of the
|
|
* "oversampling" in the frequency domain. Such oversampling is needed to
|
|
* improve the precision of the minimum-phase transform. If the filter's
|
|
* attenuation is high, this multiplier should be increased or otherwise the
|
|
* required attenuation will not be reached due to "smoothing" effect of this
|
|
* transform.
|
|
* @param DoFinalMul "True" if the final multiplication after transform should
|
|
* be performed or not. Such multiplication returns the gain of the signal to
|
|
* its original value. This parameter can be set to "false" if normalization
|
|
* of the resulting filter kernel is planned to be used.
|
|
* @param[out] DCGroupDelay If not NULL, this variable receives group delay
|
|
* at DC offset, in samples (can be a non-integer value).
|
|
*/
|
|
|
|
inline void calcMinPhaseTransform( double* const Kernel, const int KernelLen,
|
|
const int LenMult = 2, const bool DoFinalMul = true,
|
|
double* const DCGroupDelay = NULL )
|
|
{
|
|
R8BASSERT( KernelLen > 0 );
|
|
R8BASSERT( LenMult >= 2 );
|
|
|
|
const int LenBits = getBitOccupancy(( KernelLen * LenMult ) - 1 );
|
|
const int Len = 1 << LenBits;
|
|
const int Len2 = Len >> 1;
|
|
int i;
|
|
|
|
CFixedBuffer< double > ip( Len );
|
|
CFixedBuffer< double > ip2( Len2 + 1 );
|
|
|
|
memcpy( &ip[ 0 ], Kernel, KernelLen * sizeof( ip[ 0 ]));
|
|
memset( &ip[ KernelLen ], 0, ( Len - KernelLen ) * sizeof( ip[ 0 ]));
|
|
|
|
CDSPRealFFTKeeper ffto( LenBits );
|
|
ffto -> forward( ip );
|
|
|
|
// Create the "log |c|" spectrum while saving the original power spectrum
|
|
// in the "ip2" buffer.
|
|
|
|
#if R8B_FLOATFFT
|
|
float* const aip = (float*) &ip[ 0 ];
|
|
float* const aip2 = (float*) &ip2[ 0 ];
|
|
const float nzbias = 1e-35;
|
|
#else // R8B_FLOATFFT
|
|
double* const aip = &ip[ 0 ];
|
|
double* const aip2 = &ip2[ 0 ];
|
|
const double nzbias = 1e-300;
|
|
#endif // R8B_FLOATFFT
|
|
|
|
aip2[ 0 ] = aip[ 0 ];
|
|
aip[ 0 ] = log( fabs( aip[ 0 ]) + nzbias );
|
|
aip2[ Len2 ] = aip[ 1 ];
|
|
aip[ 1 ] = log( fabs( aip[ 1 ]) + nzbias );
|
|
|
|
for( i = 1; i < Len2; i++ )
|
|
{
|
|
aip2[ i ] = sqrt( aip[ i * 2 ] * aip[ i * 2 ] +
|
|
aip[ i * 2 + 1 ] * aip[ i * 2 + 1 ]);
|
|
|
|
aip[ i * 2 ] = log( aip2[ i ] + nzbias );
|
|
aip[ i * 2 + 1 ] = 0.0;
|
|
}
|
|
|
|
// Convert to cepstrum and apply discrete Hilbert transform.
|
|
|
|
ffto -> inverse( ip );
|
|
|
|
const double m1 = ffto -> getInvMulConst();
|
|
const double m2 = -m1;
|
|
|
|
ip[ 0 ] = 0.0;
|
|
|
|
for( i = 1; i < Len2; i++ )
|
|
{
|
|
ip[ i ] *= m1;
|
|
}
|
|
|
|
ip[ Len2 ] = 0.0;
|
|
|
|
for( i = Len2 + 1; i < Len; i++ )
|
|
{
|
|
ip[ i ] *= m2;
|
|
}
|
|
|
|
// Convert Hilbert-transformed cepstrum back to the "log |c|" spectrum and
|
|
// perform its exponentiation, multiplied by the power spectrum previously
|
|
// saved in the "ip2" buffer.
|
|
|
|
ffto -> forward( ip );
|
|
|
|
aip[ 0 ] = aip2[ 0 ];
|
|
aip[ 1 ] = aip2[ Len2 ];
|
|
|
|
for( i = 1; i < Len2; i++ )
|
|
{
|
|
aip[ i * 2 + 0 ] = cos( aip[ i * 2 + 1 ]) * aip2[ i ];
|
|
aip[ i * 2 + 1 ] = sin( aip[ i * 2 + 1 ]) * aip2[ i ];
|
|
}
|
|
|
|
ffto -> inverse( ip );
|
|
|
|
if( DoFinalMul )
|
|
{
|
|
for( i = 0; i < KernelLen; i++ )
|
|
{
|
|
Kernel[ i ] = ip[ i ] * m1;
|
|
}
|
|
}
|
|
else
|
|
{
|
|
memcpy( &Kernel[ 0 ], &ip[ 0 ], KernelLen * sizeof( Kernel[ 0 ]));
|
|
}
|
|
|
|
if( DCGroupDelay != NULL )
|
|
{
|
|
double tmp;
|
|
|
|
calcFIRFilterResponseAndGroupDelay( Kernel, KernelLen, 0.0,
|
|
tmp, tmp, *DCGroupDelay );
|
|
}
|
|
}
|
|
|
|
} // namespace r8b
|
|
|
|
#endif // VOX_CDSPREALFFT_INCLUDED
|