/*
* Copyright (C) 2010-2015 Thorsten Liebig (Thorsten.Liebig@gmx.de)
*
* 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 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 General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see .
*/
#ifndef PROCESSING_H
#define PROCESSING_H
#ifndef __GNUC__ // not GCC
#include
#endif
#include
typedef std::complex double_complex;
#define _I double_complex(0.0,1.0)
#include
#include
#include
#include
#include
#include
#include
#include
#define _USE_MATH_DEFINES
#include "Common/engine_interface_base.h"
class Operator_Base;
class Processing
{
public:
virtual ~Processing();
enum MeshType { CARTESIAN_MESH, CYLINDRICAL_MESH};
//! Set the interface to the engine. Each processing needs its own engine interface. This class will take ownership and cleanup the interface on deletion!
void SetEngineInterface(Engine_Interface_Base* eng_if);
virtual void SetName(std::string val) {m_Name=val;}
virtual void SetName(std::string val, int number);
virtual std::string GetName() const {return m_Name;}
//! Get the name for this processing, will be used in file description.
virtual std::string GetProcessingName() const = 0;
virtual void InitProcess() {};
virtual void Reset();
virtual void DefineStartStopCoord(double* dstart, double* dstop);
virtual void ShowSnappedCoords();
void SetProcessInterval(unsigned int interval);
void SetProcessStartStopTime(double start, double stop);
void AddStep(unsigned int step);
void AddSteps(std::vector steps);
void AddFrequency(double freq);
void AddFrequency(std::vector *freqs);
bool CheckTimestep();
//! Process data prior to the simulation run.
virtual void PreProcess() {};
//! Process data during simulation run.
virtual int Process() {return GetNextInterval();}
//! Process data after simulation has finished.
virtual void PostProcess();
//! If disabled, Process() will do nothing...
virtual void SetEnable(bool val) {Enabled=val;}
//! If disabled, Process() will do nothing...
virtual bool GetEnable() const {return Enabled;}
virtual void SetWeight(double weight) {m_weight=weight;}
virtual double GetWeight() {return m_weight;}
//! Invoke this flag to flush all stored data to disk
virtual void FlushNext() {m_Flush = true;}
virtual void FlushData() {};
void SetMeshType(MeshType meshType) {m_Mesh_Type=meshType;}
//! Set the dump precision
void SetPrecision(unsigned int val) {m_precision = val;}
//! Dump probe geometry to file (will obay main or dual mesh property)
virtual void DumpBox2File(std::string vtkfilenameprefix) const {DumpBox2File(vtkfilenameprefix,m_dualMesh);}
//! Dump probe geometry to file
virtual void DumpBox2File(std::string vtkfilenameprefix, bool dualMesh) const;
virtual void SetDualMesh(bool val) {m_dualMesh=val;}
virtual void SetDualTime(bool val) {m_dualTime=val;}
protected:
Processing(Engine_Interface_Base* eng_if);
Engine_Interface_Base* m_Eng_Interface;
const Operator_Base* Op;
MeshType m_Mesh_Type;
unsigned int m_precision;
std::string m_Name;
bool m_Flush;
double m_weight;
bool Enabled;
int GetNextInterval() const;
unsigned int ProcessInterval;
size_t m_PS_pos; //! current position in list of processing steps
std::vector m_ProcessSteps; //! list of processing steps
//! Vector of frequency samples
std::vector m_FD_Samples;
//! Number of samples already processed
unsigned int m_FD_SampleCount;
//! Sampling interval needed for the FD_Samples
unsigned int m_FD_Interval;
//! define if given coords are on main or dualMesh (default is false)
bool m_dualMesh;
//! define if given processing uses the dual time concept (default is false);
bool m_dualTime;
//! define the snap method used for this processing
int m_SnapMethod;
//! dimension of the snapped box
int m_Dimension;
//! define/store snapped start/stop coords as mesh index
unsigned int start[3];
unsigned int stop[3];
//! start/stop timestep
unsigned int startTS, stopTS;
//! define/store if snapped start/stop coords are inside the field domain
bool m_start_inside[3];
bool m_stop_inside[3];
std::ofstream file;
std::string m_filename;
virtual void OpenFile(std::string outfile);
};
class ProcessingArray
{
public:
ProcessingArray(unsigned int maximalInterval) {maxInterval=maximalInterval;}
~ProcessingArray() {};
void AddProcessing(Processing* proc);
void InitAll();
//! Invoke this flag to flush all stored data to disk for all processings on next Process()
void FlushNext();
void Reset();
//! Deletes all given processing's, can be helpful, but use carefull!!!
void DeleteAll();
//! Invoke PreProcess() on all Processings.
void PreProcess();
//! Invoke Process() on all Processings. Will return the smallest next iteration interval.
int Process();
//! Invoke PostProcess() on all Processings.
void PostProcess();
void DumpBoxes2File(std::string vtkfilenameprefix ) const;
size_t GetNumberOfProcessings() const {return ProcessArray.size();}
Processing* GetProcessing(size_t number) {return ProcessArray.at(number);}
protected:
unsigned int maxInterval;
std::vector ProcessArray;
};
#endif // PROCESSING_H