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/*
-----------------------------------------------------------------------
Copyright: 2010-2021, imec Vision Lab, University of Antwerp
2014-2021, CWI, Amsterdam
Contact: astra@astra-toolbox.com
Website: http://www.astra-toolbox.com/
This file is part of the ASTRA Toolbox.
The ASTRA Toolbox 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.
The ASTRA Toolbox 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 the ASTRA Toolbox. If not, see <http://www.gnu.org/licenses/>.
-----------------------------------------------------------------------
*/
#ifndef _INC_ASTRA_ASTRAOBJECTMANAGER
#define _INC_ASTRA_ASTRAOBJECTMANAGER
#include <map>
#include <sstream>
#include "Globals.h"
#include "Singleton.h"
#include "Projector2D.h"
#include "Projector3D.h"
#include "Float32Data2D.h"
#include "Float32Data3D.h"
#include "SparseMatrix.h"
#include "Algorithm.h"
namespace astra {
/**
* This class contains functionality to store objects. A unique index handle
* will be assigned to each data object by which it can be accessed in the
* future. Indices are always >= 1.
*
* We store them in a special common base class to make indices unique
* among all ObjectManagers.
*/
class CAstraObjectManagerBase {
public:
virtual std::string getInfo(int index) const =0;
virtual void remove(int index) =0;
virtual std::string getType() const =0;
};
class _AstraExport CAstraIndexManager : public Singleton<CAstraIndexManager> {
public:
CAstraIndexManager() : m_iLastIndex(0) { }
int store(CAstraObjectManagerBase* m) {
m_table[++m_iLastIndex] = m;
return m_iLastIndex;
}
CAstraObjectManagerBase* get(int index) const {
std::map<int, CAstraObjectManagerBase*>::const_iterator i;
i = m_table.find(index);
if (i != m_table.end())
return i->second;
else
return 0;
}
void remove(int index) {
std::map<int, CAstraObjectManagerBase*>::iterator i;
i = m_table.find(index);
if (i != m_table.end())
m_table.erase(i);
}
private:
/** The index last handed out
*/
int m_iLastIndex;
std::map<int, CAstraObjectManagerBase*> m_table;
};
template <typename T>
class CAstraObjectManager : public CAstraObjectManagerBase {
public:
/** Default constructor.
*/
CAstraObjectManager();
/** Destructor.
*/
~CAstraObjectManager();
/** Store the object in the manager and assign a unique index handle to it.
*
* @param _pObject A pointer to the object that should be stored.
* @return The index of the stored data object. If the index in negative, an error occurred
* and the object was NOT stored.
*/
int store(T* _pObject);
/** Does the manager contain an object with the index _iIndex?
*
* @param _iIndex Index handle to the data object in question.
* @return True if the manager contains an object with the index handle _iIndex.
*/
bool hasIndex(int _iIndex) const;
/** Fetch the object to which _iIndex refers to.
*
* @param _iIndex Index handle to the data object in question.
* @return Pointer to the stored data object. A null pointer is returned if no object with index _iIndex is found.
*/
T* get(int _iIndex) const;
/** Delete an object that was previously stored. This actually DELETES the objecy. Therefore, after this
* function call, the object in question will have passed on. It will be no more. It will have ceased
* to be. It will be expired and will go to meet its maker. Bereft of life, it will rest in peace.
* It will be an EX-OBJECT.
*
* @param _iIndex Index handle to the object in question.
* @return Error code. 0 for success.
*/
void remove(int _iIndex);
/** Get the index of the object, zero if it doesn't exist.
*
* @param _pObject The data object.
* @return Index of the stored object, 0 if not found.
*/
int getIndex(const T* _pObject) const;
/** Clear all data. This will also delete all the content of each object.
*/
void clear();
/** Get info of object.
*/
std::string getInfo(int index) const;
/** Get list with info of all managed objects.
*/
std::string info();
protected:
/** Map each data object to a unique index.
*/
std::map<int, T*> m_mIndexToObject;
};
//----------------------------------------------------------------------------------------
// Constructor
template <typename T>
CAstraObjectManager<T>::CAstraObjectManager()
{
}
//----------------------------------------------------------------------------------------
// Destructor
template <typename T>
CAstraObjectManager<T>::~CAstraObjectManager()
{
}
//----------------------------------------------------------------------------------------
// store data
template <typename T>
int CAstraObjectManager<T>::store(T* _pDataObject)
{
int iIndex = CAstraIndexManager::getSingleton().store(this);
m_mIndexToObject[iIndex] = _pDataObject;
return iIndex;
}
//----------------------------------------------------------------------------------------
// has data?
template <typename T>
bool CAstraObjectManager<T>::hasIndex(int _iIndex) const
{
typename std::map<int,T*>::const_iterator it = m_mIndexToObject.find(_iIndex);
return it != m_mIndexToObject.end();
}
//----------------------------------------------------------------------------------------
// get data
template <typename T>
T* CAstraObjectManager<T>::get(int _iIndex) const
{
typename std::map<int,T*>::const_iterator it = m_mIndexToObject.find(_iIndex);
if (it != m_mIndexToObject.end())
return it->second;
else
return 0;
}
//----------------------------------------------------------------------------------------
// delete data
template <typename T>
void CAstraObjectManager<T>::remove(int _iIndex)
{
// find data
typename std::map<int,T*>::iterator it = m_mIndexToObject.find(_iIndex);
if (it == m_mIndexToObject.end())
return;
// delete data
delete (*it).second;
// delete from map
m_mIndexToObject.erase(it);
CAstraIndexManager::getSingleton().remove(_iIndex);
}
//----------------------------------------------------------------------------------------
// Get Index
template <typename T>
int CAstraObjectManager<T>::getIndex(const T* _pObject) const
{
for (typename std::map<int,T*>::const_iterator it = m_mIndexToObject.begin(); it != m_mIndexToObject.end(); it++) {
if ((*it).second == _pObject) return (*it).first;
}
return 0;
}
//----------------------------------------------------------------------------------------
// clear
template <typename T>
void CAstraObjectManager<T>::clear()
{
for (typename std::map<int,T*>::iterator it = m_mIndexToObject.begin(); it != m_mIndexToObject.end(); it++) {
// delete data
delete (*it).second;
(*it).second = 0;
}
m_mIndexToObject.clear();
}
//----------------------------------------------------------------------------------------
// Print info to string
template <typename T>
std::string CAstraObjectManager<T>::getInfo(int index) const {
typename std::map<int,T*>::const_iterator it = m_mIndexToObject.find(index);
if (it == m_mIndexToObject.end())
return "";
const T* pObject = it->second;
std::stringstream res;
res << index << " \t";
if (pObject->isInitialized()) {
res << "v ";
} else {
res << "x ";
}
res << pObject->description();
return res.str();
}
template <typename T>
std::string CAstraObjectManager<T>::info() {
std::stringstream res;
res << "id init description" << std::endl;
res << "-----------------------------------------" << std::endl;
for (typename std::map<int,T*>::const_iterator it = m_mIndexToObject.begin(); it != m_mIndexToObject.end(); it++) {
res << getInfo(it->first) << std::endl;
}
res << "-----------------------------------------" << std::endl;
return res.str();
}
//----------------------------------------------------------------------------------------
// Create the necessary Object Managers
/**
* This class contains functionality to store 2D projector objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CProjector2DManager : public Singleton<CProjector2DManager>, public CAstraObjectManager<CProjector2D>
{
virtual std::string getType() const { return "projector2d"; }
};
/**
* This class contains functionality to store 3D projector objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CProjector3DManager : public Singleton<CProjector3DManager>, public CAstraObjectManager<CProjector3D>
{
virtual std::string getType() const { return "projector3d"; }
};
/**
* This class contains functionality to store 2D data objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CData2DManager : public Singleton<CData2DManager>, public CAstraObjectManager<CFloat32Data2D>
{
virtual std::string getType() const { return "data2d"; }
};
/**
* This class contains functionality to store 3D data objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CData3DManager : public Singleton<CData3DManager>, public CAstraObjectManager<CFloat32Data3D>
{
virtual std::string getType() const { return "data3d"; }
};
/**
* This class contains functionality to store algorithm objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CAlgorithmManager : public Singleton<CAlgorithmManager>, public CAstraObjectManager<CAlgorithm>
{
virtual std::string getType() const { return "algorithm"; }
};
/**
* This class contains functionality to store matrix objects. A unique index handle will be
* assigned to each data object by which it can be accessed in the future.
* Indices are always >= 1.
*/
class _AstraExport CMatrixManager : public Singleton<CMatrixManager>, public CAstraObjectManager<CSparseMatrix>
{
virtual std::string getType() const { return "matrix"; }
};
} // end namespace
#endif
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