/usr/include/CLAM/SpectrumSubstracter2.hxx is in libclam-dev 1.4.0-6.
This file is owned by root:root, with mode 0o644.
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* Copyright (c) 2001-2004 MUSIC TECHNOLOGY GROUP (MTG)
* UNIVERSITAT POMPEU FABRA
*
*
* This program 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 2 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
*
*/
#ifndef _SPECTRUM_Substracter2_
#define _SPECTRUM_Substracter2_
#include "Processing.hxx"
#include "DynamicType.hxx"
#include "InPort.hxx"
#include "OutPort.hxx"
#include "Spectrum.hxx"
namespace CLAM {
class SpecSubstracter2Config: public ProcessingConfig
{
public:
DYNAMIC_TYPE_USING_INTERFACE (SpecSubstracter2Config, 0,ProcessingConfig);
};
/** This calss performs the substraction of two Spectrum processing data
* objects.
* <p>
* It Allows any possible attribute configuration in its inputs and in
* its output, but it performs faster when prototype configuration of
* the data is specified using SetPrototypes(...), in certain
* situations:
* <ul>
* <li> When all the inputs and the outputs have a common attirbute
* (not the BPF), and the same scale.
* <li> When one of the inputs has just a BPF attribute, and both the
* other input and the output have a common (non-BPF) attribute
* with the same scale in both objects.
* <li> In other cases, at least a vector conversion will be executed
* in one of the involved processing data objects. In some bad
* situations two conversions might be needed.
* </ul><p>
* @todo
* @see SpectrumSubstracter2
*/
class SpectrumSubstracter2: public Processing {
SpecSubstracter2Config mConfig;
/** Size of the input/output vectors */
int mSize;
InPort<Spectrum> mIn1;
InPort<Spectrum> mIn2;
OutPort<Spectrum> mOut;
/** Possible configuration/prototype states */
typedef enum {
// Type states in with the same attribute is used for all
// of the inputs and the outputs (it may or may not be
// present; in the second case it will be Substracted at Do(...)
// time.
SMagPhase, SComplex, SPolar,
// BPF output sum
SBPF,
// Type states with only a BPF attribute in one of the
// inputs, other type in the other input and the
// output. The non-BPF attribute may or may not be
// instantiated. In the second case it will be Substracted at
// Do(...) time.
SBPFMagPhase, SBPFComplex, SBPFPolar, SMagPhaseBPF,
SComplexBPF, SPolarBPF,
// State in which nothing is known about prototypes.
SOther
} PrototypeState;
/** Possible scale combinations */
typedef enum { Slinlin, Sloglog, Slinlog, Sloglin} ScaleState;
/** Config/Prototype state */
PrototypeState mProtoState;
/** Scale combination state */
ScaleState mScaleState;
/** OBSOLETE */
std::string NewUniqueName();
const char *GetClassName() const {return "SpectrumSubstracter2";}
/** Config change method
* @pre argument should be an SpecSubstracter2Config
*/
bool ConcreteConfigure(const ProcessingConfig&);
public:
SpectrumSubstracter2();
SpectrumSubstracter2(const SpecSubstracter2Config &c);
~SpectrumSubstracter2() {};
const ProcessingConfig &GetConfig() const { return mConfig;}
bool Do(void);
bool Do(Spectrum& in1, Spectrum& in2, Spectrum& out);
// Port interfaces.
/** Change the internal type state.
* Apart from prototype configuration, the Size, Scale and
* SpectralRange attributes of each Spectrum are also
* checked.
*/
bool SetPrototypes(const Spectrum& in1,const Spectrum& in2,const Spectrum& out);
bool SetPrototypes();
bool UnsetPrototypes();
bool MayDisableExecution() const {return true;}
private:
/** Unoptimised internal multiplication method, when
* prototypes are not known (state SOther)
*/
inline void Substract(Spectrum& in1, Spectrum& in2, Spectrum& out);
// Substracter methods for optimized configurations of the inputs/output
// Direct sums
inline void SubstractMagPhase(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractMagPhaseLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractMagPhaseLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractMagPhaseLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractComplex(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractComplexLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractComplexLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractComplexLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractPolar(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractPolarLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractPolarLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractPolarLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
// BPF Substracter
inline void SubstractBPF(Spectrum& in1, Spectrum& in2, Spectrum& out);
// Substracting BPFs to non-BPFs.
inline void SubstractBPFLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFMagPhase(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractMagPhaseBPF(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFMagPhaseLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFMagPhaseLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFMagPhaseLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFMagPhaseLogLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFComplex(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractComplexBPF(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFComplexLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFComplexLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFComplexLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFComplexLogLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFPolar(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractPolarBPF(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFPolarLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFPolarLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFPolarLinLog(Spectrum& in1, Spectrum& in2, Spectrum& out);
inline void SubstractBPFPolarLogLin(Spectrum& in1, Spectrum& in2, Spectrum& out);
};
}
#endif // _SPECTRUM_Substracter_
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