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Rename in peo

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git-svn-id: svn://scm.gforge.inria.fr/svnroot/paradiseo@841 331e1502-861f-0410-8da2-ba01fb791d7f
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canape 2007-12-10 08:37:23 +00:00
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trunk/paradiseo-peo/src/peoSynchronousMultiStart.h
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/*
* <peoSynchronousMultiStart.h>
* Copyright (C) DOLPHIN Project-Team, INRIA Futurs, 2006-2007
* (C) OPAC Team, LIFL, 2002-2007
*
* Sebastien Cahon, Alexandru-Adrian Tantar
*
* This software is governed by the CeCILL license under French law and
* abiding by the rules of distribution of free software. You can use,
* modify and/ or redistribute the software under the terms of the CeCILL
* license as circulated by CEA, CNRS and INRIA at the following URL
* "http://www.cecill.info".
*
* As a counterpart to the access to the source code and rights to copy,
* modify and redistribute granted by the license, users are provided only
* with a limited warranty and the software's author, the holder of the
* economic rights, and the successive licensors have only limited liability.
*
* In this respect, the user's attention is drawn to the risks associated
* with loading, using, modifying and/or developing or reproducing the
* software by the user in light of its specific status of free software,
* that may mean that it is complicated to manipulate, and that also
* therefore means that it is reserved for developers and experienced
* professionals having in-depth computer knowledge. Users are therefore
* encouraged to load and test the software's suitability as regards their
* requirements in conditions enabling the security of their systems and/or
* data to be ensured and, more generally, to use and operate it in the
* same conditions as regards security.
* The fact that you are presently reading this means that you have had
* knowledge of the CeCILL license and that you accept its terms.
*
* ParadisEO WebSite : http://paradiseo.gforge.inria.fr
* Contact: paradiseo-help@lists.gforge.inria.fr
*
*/
#ifndef __peoSynchronousMultiStart_h
#define __peoSynchronousMultiStart_h
#include <vector>
#include "core/service.h"
#include "core/messaging.h"
template < typename EntityType > class peoSynchronousMultiStart : public Service
{
public:
template < typename AlgorithmType > peoSynchronousMultiStart( AlgorithmType& externalAlgorithm )
{
singularAlgorithm = new Algorithm< AlgorithmType >( externalAlgorithm );
algorithms.push_back( singularAlgorithm );
aggregationFunction = new NoAggregationFunction();
}
template < typename AlgorithmReturnType, typename AlgorithmDataType > peoSynchronousMultiStart( AlgorithmReturnType (*externalAlgorithm)( AlgorithmDataType& ) )
{
singularAlgorithm = new FunctionAlgorithm< AlgorithmReturnType, AlgorithmDataType >( externalAlgorithm );
algorithms.push_back( singularAlgorithm );
aggregationFunction = new NoAggregationFunction();
}
template < typename AlgorithmType, typename AggregationFunctionType > peoSynchronousMultiStart( std::vector< AlgorithmType* >& externalAlgorithms, AggregationFunctionType& externalAggregationFunction )
{
for ( unsigned int index = 0; index < externalAlgorithms.size(); index++ )
{
algorithms.push_back( new Algorithm< AlgorithmType >( *externalAlgorithms[ index ] ) );
}
aggregationFunction = new AggregationAlgorithm< AggregationFunctionType >( externalAggregationFunction );
}
template < typename AlgorithmReturnType, typename AlgorithmDataType, typename AggregationFunctionType >
peoSynchronousMultiStart( std::vector< AlgorithmReturnType (*)( AlgorithmDataType& ) >& externalAlgorithms,
AggregationFunctionType& externalAggregationFunction )
{
for ( unsigned int index = 0; index < externalAlgorithms.size(); index++ )
{
algorithms.push_back( new FunctionAlgorithm< AlgorithmReturnType, AlgorithmDataType >( externalAlgorithms[ index ] ) );
}
aggregationFunction = new AggregationAlgorithm< AggregationFunctionType >( externalAggregationFunction );
}
~peoSynchronousMultiStart()
{
for ( unsigned int index = 0; index < data.size(); index++ ) delete data[ index ];
for ( unsigned int index = 0; index < algorithms.size(); index++ ) delete algorithms[ index ];
delete aggregationFunction;
}
template < typename Type > void operator()( Type& externalData )
{
for ( typename Type::iterator externalDataIterator = externalData.begin(); externalDataIterator != externalData.end(); externalDataIterator++ )
{
data.push_back( new DataType< EntityType >( *externalDataIterator ) );
}
functionIndex = dataIndex = idx = num_term = 0;
requestResourceRequest( data.size() * algorithms.size() );
stop();
}
template < typename Type > void operator()( const Type& externalDataBegin, const Type& externalDataEnd )
{
for ( Type externalDataIterator = externalDataBegin; externalDataIterator != externalDataEnd; externalDataIterator++ )
{
data.push_back( new DataType< EntityType >( *externalDataIterator ) );
}
functionIndex = dataIndex = idx = num_term = 0;
requestResourceRequest( data.size() * algorithms.size() );
stop();
}
void packData();
void unpackData();
void execute();
void packResult();
void unpackResult();
void notifySendingData();
void notifySendingAllResourceRequests();
private:
template < typename Type > struct DataType;
struct AbstractDataType
{
virtual ~AbstractDataType()
{ }
template < typename Type > operator Type& ()
{
return ( dynamic_cast< DataType< Type >& >( *this ) ).data;
}
};
template < typename Type > struct DataType : public AbstractDataType
{
DataType( Type& externalData ) : data( externalData )
{ }
Type& data;
};
struct AbstractAlgorithm
{
virtual ~AbstractAlgorithm()
{ }
virtual void operator()( AbstractDataType& dataTypeInstance )
{}
};
template < typename AlgorithmType > struct Algorithm : public AbstractAlgorithm
{
Algorithm( AlgorithmType& externalAlgorithm ) : algorithm( externalAlgorithm )
{ }
void operator()( AbstractDataType& dataTypeInstance )
{
algorithm( dataTypeInstance );
}
AlgorithmType& algorithm;
};
template < typename AlgorithmReturnType, typename AlgorithmDataType > struct FunctionAlgorithm : public AbstractAlgorithm
{
FunctionAlgorithm( AlgorithmReturnType (*externalAlgorithm)( AlgorithmDataType& ) ) : algorithm( externalAlgorithm )
{ }
void operator()( AbstractDataType& dataTypeInstance )
{
algorithm( dataTypeInstance );
}
AlgorithmReturnType (*algorithm)( AlgorithmDataType& );
};
struct AbstractAggregationAlgorithm
{
virtual ~AbstractAggregationAlgorithm()
{ }
virtual void operator()( AbstractDataType& dataTypeInstanceA, AbstractDataType& dataTypeInstanceB )
{};
};
template < typename AggregationAlgorithmType > struct AggregationAlgorithm : public AbstractAggregationAlgorithm
{
AggregationAlgorithm( AggregationAlgorithmType& externalAggregationAlgorithm ) : aggregationAlgorithm( externalAggregationAlgorithm )
{ }
void operator()( AbstractDataType& dataTypeInstanceA, AbstractDataType& dataTypeInstanceB )
{
aggregationAlgorithm( dataTypeInstanceA, dataTypeInstanceB );
}
AggregationAlgorithmType& aggregationAlgorithm;
};
struct NoAggregationFunction : public AbstractAggregationAlgorithm
{
void operator()( AbstractDataType& dataTypeInstanceA, AbstractDataType& dataTypeInstanceB )
{
static_cast< EntityType& >( dataTypeInstanceA ) = static_cast< EntityType& >( dataTypeInstanceB );
}
};
AbstractAlgorithm* singularAlgorithm;
std::vector< AbstractAlgorithm* > algorithms;
AbstractAggregationAlgorithm* aggregationFunction;
EntityType entityTypeInstance;
std::vector< AbstractDataType* > data;
unsigned idx;
unsigned num_term;
unsigned dataIndex;
unsigned functionIndex;
};
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::packData()
{
pack( functionIndex );
pack( idx );
pack( ( EntityType& ) *data[ idx++ ] );
// done with functionIndex for the entire data set - moving to another
// function/algorithm starting all over with the entire data set ( idx is set to 0 )
if ( idx == data.size() )
{
++functionIndex;
idx = 0;
}
}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::unpackData()
{
unpack( functionIndex );
unpack( dataIndex );
unpack( entityTypeInstance );
}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::execute()
{
// wrapping the unpacked data - the definition of an abstract algorithm imposes
// that its internal function operator acts only on abstract data types
AbstractDataType* entityWrapper = new DataType< EntityType >( entityTypeInstance );
algorithms[ functionIndex ]->operator()( *entityWrapper );
delete entityWrapper;
}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::packResult()
{
pack( dataIndex );
pack( entityTypeInstance );
}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::unpackResult()
{
unpack( dataIndex );
unpack( entityTypeInstance );
// wrapping the unpacked data - the definition of an abstract algorithm imposes
// that its internal function operator acts only on abstract data types
AbstractDataType* entityWrapper = new DataType< EntityType >( entityTypeInstance );
aggregationFunction->operator()( *data[ dataIndex ], *entityWrapper );
delete entityWrapper;
num_term++;
if ( num_term == data.size() * algorithms.size() )
{
getOwner()->setActive();
resume();
}
}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::notifySendingData()
{}
template < typename EntityType > void peoSynchronousMultiStart< EntityType >::notifySendingAllResourceRequests()
{
getOwner()->setPassive();
}
#endif