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eodev/eo/src/es/make_op_real.h

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// -*- mode: c++; c-indent-level: 4; c++-member-init-indent: 8; comment-column: 35; -*-
//-----------------------------------------------------------------------------
// make_op.h - the real-valued version
// (c) Maarten Keijzer, Marc Schoenauer and GeNeura Team, 2001
/*
This library is free software; you can redistribute it and/or
modify it under the terms of the GNU Lesser General Public
License as published by the Free Software Foundation; either
version 2 of the License, or (at your option) any later version.
This library 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
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with this library; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA
Contact: todos@geneura.ugr.es, http://geneura.ugr.es
Marc.Schoenauer@polytechnique.fr
mkeijzer@dhi.dk
*/
//-----------------------------------------------------------------------------
#ifndef _make_op_h
#define _make_op_h
// the operators
#include <eoOp.h>
#include <eoGenOp.h>
#include <eoCloneOps.h>
#include <eoOpContainer.h>
// combinations of simple eoOps (eoMonOp and eoQuadOp)
#include <eoProportionalCombinedOp.h>
// the specialized Real stuff
#include <es/eoReal.h>
#include <es/eoEsChromInit.h>
#include <es/eoRealOp.h>
#include <es/eoNormalMutation.h>
// also need the parser and param includes
#include <utils/eoParser.h>
#include <utils/eoState.h>
/*
* This function builds the operators that will be applied to the eoReal
*
* It uses a parser (to get user parameters) and a state (to store the memory)
* the last argument is an individual, needed for 2 reasons
* it disambiguates the call after instanciations
* some operator might need some private information about the indis
*
* This is why the template is the complete EOT even though only the fitness
* is actually templatized here: the following only applies to bitstrings
*
* Note : the last parameter is an eoInit: if some operator needs some info
* about the gneotypes, the init has it all (e.g. bounds, ...)
* Simply do
* EOT myEO;
* _init(myEO);
* and myEO is then an ACTUAL object
*/
template <class EOT>
eoGenOp<EOT> & do_make_op(eoParameterLoader& _parser, eoState& _state, eoRealInitBounded<EOT>& _init)
{
// First, decide whether the objective variables are bounded
eoValueParam<eoParamParamType>& boundsParam = _parser.createParam(eoParamParamType("(0,1)"), "objectBounds", "Bounds for variables (unbounded if absent)", 'B', "Variation Operators");
// get vector size
unsigned vecSize = _init.size();
// the bounds pointer
eoRealVectorBounds * ptBounds;
if (_parser.isItThere(boundsParam)) // otherwise, no bounds
{
/////Warning: this code should probably be replaced by creating
///// some eoValueParam<eoRealVectorBounds> with specific implementation
//// in eoParser.cpp. At the moemnt, it is there (cf also make_genotype
eoParamParamType & ppBounds = boundsParam.value(); // pair<string,vector<string> >
// transform into a vector<double>
vector<double> v;
vector<string>::iterator it;
for (it=ppBounds.second.begin(); it<ppBounds.second.end(); it++)
{
istrstream is(it->c_str());
double r;
is >> r;
v.push_back(r);
}
// now create the eoRealVectorBounds object
if (v.size() == 2) // a min and a max for all variables
ptBounds = new eoRealVectorBounds(vecSize, v[0], v[1]);
else // no time now
throw runtime_error("Sorry, only unique bounds for all variables implemented at the moment. Come back later");
// we need to give ownership of this pointer to somebody
/////////// end of temporary code
}
else // no param for bounds was given
ptBounds = new eoRealVectorNoBounds(vecSize); // DON'T USE eoDummyVectorNoBounds
// as it does not have any dimension
// this is a temporary version(!),
// while Maarten codes the full tree-structured general operator input
// BTW we must leave that simple version available somehow, as it is the one
// that 90% people use!
eoValueParam<string>& operatorParam = _parser.createParam(string("SGA"), "operator", "Description of the operator (SGA only now)", 'o', "Variation Operators");
if (operatorParam.value() != string("SGA"))
throw runtime_error("Sorry, only SGA-like operator available right now\n");
// now we read Pcross and Pmut,
// the relative weights for all crossovers -> proportional choice
// the relative weights for all mutations -> proportional choice
// and create the eoGenOp that is exactly
// crossover with pcross + mutation with pmut
eoValueParam<double>& pCrossParam = _parser.createParam(0.6, "pCross", "Probability of Crossover", 'C', "Variation Operators" );
// minimum check
if ( (pCrossParam.value() < 0) || (pCrossParam.value() > 1) )
throw runtime_error("Invalid pCross");
eoValueParam<double>& pMutParam = _parser.createParam(0.1, "pMut", "Probability of Mutation", 'M', "Variation Operators" );
// minimum check
if ( (pMutParam.value() < 0) || (pMutParam.value() > 1) )
throw runtime_error("Invalid pMut");
// the crossovers
/////////////////
// the parameters
eoValueParam<double>& segmentRateParam = _parser.createParam(double(1.0), "segmentRate", "Relative rate for segment crossover", 's', "Variation Operators" );
// minimum check
if ( (segmentRateParam.value() < 0) )
throw runtime_error("Invalid segmentRate");
eoValueParam<double>& arithmeticRateParam = _parser.createParam(double(2.0), "arithmeticRate", "Relative rate for arithmetic crossover", 'A', "Variation Operators" );
// minimum check
if ( (arithmeticRateParam.value() < 0) )
throw runtime_error("Invalid arithmeticRate");
// minimum check
bool bCross = true;
if (segmentRateParam.value()+arithmeticRateParam.value()==0)
{
cerr << "Warning: no crossover" << endl;
bCross = false;
}
// Create the CombinedQuadOp
eoPropCombinedQuadOp<EOT> *ptCombinedQuadOp = NULL;
eoQuadOp<EOT> *ptQuad = NULL;
if (bCross)
{
// segment crossover for bitstring - pass it the bounds
ptQuad = new eoSegmentCrossover<EOT>(*ptBounds);
_state.storeFunctor(ptQuad);
ptCombinedQuadOp = new eoPropCombinedQuadOp<EOT>(*ptQuad, segmentRateParam.value());
// arithmetic crossover
ptQuad = new eoArithmeticCrossover<EOT>(*ptBounds);
_state.storeFunctor(ptQuad);
ptCombinedQuadOp->add(*ptQuad, arithmeticRateParam.value());
// don't forget to store the CombinedQuadOp
_state.storeFunctor(ptCombinedQuadOp);
}
// the mutations
/////////////////
// the parameters
eoValueParam<double> & epsilonParam = _parser.createParam(0.01, "epsilon", "Half-size of interval for Uniform Mutation", 'e', "Variation Operators" );
// minimum check
if ( (epsilonParam.value() < 0) )
throw runtime_error("Invalid epsilon");
eoValueParam<double> & uniformMutRateParam = _parser.createParam(1.0, "uniformMutRate", "Relative rate for uniform mutation", 'u', "Variation Operators" );
// minimum check
if ( (uniformMutRateParam.value() < 0) )
throw runtime_error("Invalid uniformMutRate");
eoValueParam<double> & detMutRateParam = _parser.createParam(1.0, "detMutRate", "Relative rate for deterministic uniform mutation", 'd', "Variation Operators" );
// minimum check
if ( (detMutRateParam.value() < 0) )
throw runtime_error("Invalid detMutRate");
eoValueParam<double> & normalMutRateParam = _parser.createParam(1.0, "normalMutRate", "Relative rate for Gaussian mutation", 'd', "Variation Operators" );
// minimum check
if ( (normalMutRateParam.value() < 0) )
throw runtime_error("Invalid normalMutRate");
eoValueParam<double> & sigmaParam = _parser.createParam(0.3, "sigma", "Sigma (fixed) for Gaussian mutation", 's', "Variation Operators" );
// minimum check
bool bMut = true;
if (uniformMutRateParam.value()+detMutRateParam.value()+normalMutRateParam.value()==0)
{
cerr << "Warning: no mutation" << endl;
bMut = false;
}
if (!bCross && !bMut)
throw runtime_error("No operator called in SGA operator definition!!!");
// Create the CombinedMonOp
eoPropCombinedMonOp<EOT> *ptCombinedMonOp = NULL;
eoMonOp<EOT> *ptMon = NULL;
if (bMut)
{
// uniform mutation on all components:
// offspring(i) uniformly chosen in [parent(i)-epsilon, parent(i)+epsilon]
ptMon = new eoUniformMutation<EOT>(*ptBounds, epsilonParam.value());
_state.storeFunctor(ptMon);
// create the CombinedMonOp
ptCombinedMonOp = new eoPropCombinedMonOp<EOT>(*ptMon, uniformMutRateParam.value());
// mutate exactly 1 component (uniformly) per individual
ptMon = new eoDetUniformMutation<EOT>(*ptBounds, epsilonParam.value());
_state.storeFunctor(ptMon);
ptCombinedMonOp->add(*ptMon, detMutRateParam.value());
// mutate all component using Gaussian mutation
ptMon = new eoNormalMutation<EOT>(*ptBounds, sigmaParam.value());
_state.storeFunctor(ptMon);
ptCombinedMonOp->add(*ptMon, normalMutRateParam.value());
_state.storeFunctor(ptCombinedMonOp);
}
// now build the eoGenOp:
// to simulate SGA (crossover with proba pCross + mutation with proba pMut
// we must construct
// a sequential combination of
// with proba 1, a proportional combination of
// a QuadCopy and our crossover
// with proba pMut, our mutation
// the crossover - with probability pCross
eoProportionalOp<EOT> * cross = new eoProportionalOp<EOT> ;
_state.storeFunctor(cross);
ptQuad = new eoQuadCloneOp<EOT>;
_state.storeFunctor(ptQuad);
cross->add(*ptCombinedQuadOp, pCrossParam.value()); // user crossover
cross->add(*ptQuad, 1-pCrossParam.value()); // clone operator
// now the sequential
eoSequentialOp<EOT> *op = new eoSequentialOp<EOT>;
_state.storeFunctor(op);
op->add(*cross, 1.0); // always crossover (but clone with prob 1-pCross
op->add(*ptCombinedMonOp, pMutParam.value());
// that's it!
return *op;
}
#endif
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