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paradiseo/eo/test/t-eoGenOp.cpp
nojhan eba2e14950 use eoExceptions everywhere
2020-03-27 00:48:23 +01:00

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// -*- mode: c++; c-indent-level: 4; c++-member-init-indent: 8; comment-column: 35; -*-
//-----------------------------------------------------------------------------
// eoGenOp.cpp
// (c) Maarten Keijzer and Marc Schoenauer, 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: mkeijzer@dhi.dk
Marc.Schoenauer@polytechnique.fr
*/
//-----------------------------------------------------------------------------
/** test program for the general operator - millenium version!
* uses dummy individuals
*/
#include <sstream>
#include <eo>
#include <eoPopulator.h>
#include <eoOpContainer.h>
struct Dummy : public EO<double>
{
Dummy(std::string _s="") : s(_s) {}
void printOn(std::ostream & _os) const
{
EO<double>::printOn(_os);
_os << " - " << s ;
}
std::string s;
};
typedef Dummy EOT;
unsigned int pSize; // global to be used as marker in the fitness
// DEFINITIONS of the eoOps
class monop : public eoMonOp<EOT>
{
public :
monop(char * _sig){sig=_sig;}
bool operator()(EOT& _eo)
{
_eo.s = sig + "(" + _eo.s + ")";
_eo.fitness(_eo.fitness()+pSize);
return false;
}
std::string className() const {return sig;}
private:
std::string sig;
};
class binop: public eoBinOp<EOT>
{
public :
bool operator()(EOT& _eo1, const EOT& _eo2)
{
_eo1.s = "bin(" + _eo1.s + "," + _eo2.s + ")";
double f= (_eo1.fitness()+_eo2.fitness()) * pSize;
_eo1.fitness(_eo1.fitness()+f);
return false;
}
std::string className() const {return "binop";}
};
class quadop: public eoQuadOp<EOT>
{
public :
std::string className() const {return "quadop";}
bool operator()(EOT& a, EOT& b)
{
EOT oi = a;
EOT oj = b;
a.s = "quad1(" + oi.s + "," + oj.s + ")";
b.s = "quad2(" + oj.s + "," + oi.s + ")";
double f= (a.fitness()+b.fitness()+2*pSize) * pSize;
a.fitness(a.fitness()+f);
b.fitness(b.fitness()+f);
return false;
}
};
// an eoQuadOp that does nothing
class quadClone: public eoQuadOp<EOT>
{
public :
std::string className() const {return "quadclone";}
bool operator()(EOT& , EOT& ) {return false;}
};
// User defined General Operator... adapted from Marc's example
class one2threeOp : public eoGenOp<EOT> // :-)
{
public:
unsigned max_production(void) { return 3; }
void apply(eoPopulator<EOT>& _plop)
{
EOT& eo = *_plop; // select the guy
++_plop; // advance
_plop.insert("v(" + eo.s + ", 1)");
++_plop;
_plop.insert("v(" + eo.s + ", 2)");
eo.s = "v(" + eo.s + ", 0)"; // only now change the thing
// oh right, and invalidate fitnesses
}
virtual std::string className() const {return "one2threeOp";}
};
class two2oneOp : public eoGenOp<EOT> // :-)
{
public:
unsigned max_production(void) { return 1; }
void apply(eoPopulator<EOT>& _plop)
{
EOT& eo = *_plop; // select the guy
const EOT& eo2 = _plop.select();
eo.s = "221(" + eo.s + ", " + eo2.s + ")";
// oh right, and invalidate fitnesses
}
virtual std::string className() const {return "two2oneOp";}
};
class three2threeOp : public eoGenOp<EOT> // :-)
{
public:
unsigned max_production(void) { return 3; }
void apply(eoPopulator<EOT>& _plop)
{
EOT& eo1 = *_plop; // select 1st guy
EOT& eo2 = *++_plop; // select 2nd guy
EOT& eo3 = *++_plop; // select 3rd guy
EOT a = eo1;
EOT b = eo2;
EOT c = eo3;
std::cout << "les selectionnes: a=" << a << " et b=" << b << " et c=" << c << std::endl;
eo1.s = "323-1(" + a.s + ", " + b.s + ", " + c.s + ")";
eo2.s = "323-2(" + a.s + ", " + b.s + ", " + c.s + ")";
eo3.s = "323-3(" + a.s + ", " + b.s + ", " + c.s + ")";
// oh right, and invalidate fitnesses
std::cout << "les enfants: a=" << eo1 << " et b=" << eo2 << " et c=" << eo3 << std::endl;
}
virtual std::string className() const {return "three2threeOp";}
};
// dummy intialization. Re-init if no pSize, resize first if pSize
void init(eoPop<Dummy> & _pop, unsigned _pSize)
{
if (_pSize)
{
_pop.resize(_pSize);
}
else
{
throw eoPopSizeException(_pSize,"init pop with 0 size");
}
for (unsigned i=0; i<_pSize; i++)
{
std::ostringstream os;
os << i;
_pop[i] = Dummy(os.str());
_pop[i].fitness(i);
}
}
// ok, now for the real work
int the_main(int argc, char **argv)
{
eoParser parser(argc, argv);
eoValueParam<unsigned int> parentSizeParam(
parser.createParam(unsigned(10), "parentSize", "Parent size",'P'));
pSize = parentSizeParam.value(); // global variable
eoValueParam<uint32_t> seedParam(time(0), "seed", "Random number seed", 'S');
parser.processParam( seedParam );
eo::rng.reseed(seedParam.value());
// do the following AFTER ALL PARAMETERS HAVE BEEN PROCESSED
// i.e. in case you need parameters somewhere else, postpone these
if (parser.userNeedsHelp())
{
parser.printHelp(std::cout);
exit(1);
}
////////////////////////////////// define operators
monop mon((char*)"mon1");
monop clone((char*)"clone");
binop bin;
quadop quad;
quadClone quadclone;
// our own operator
one2threeOp o2t;
two2oneOp t2o;
three2threeOp t2t;
// a selector
eoDetTournamentSelect<EOT> select;
// and a recognizable selector for testing the inbedded selector mechanism
eoBestSelect<EOT> selectBest;
// proportional selection between quad and bin
// so we either do a quad or a bin
eoProportionalOp<EOT> pOp;
pOp.add(quad, 0.1);
pOp.add(bin, 0.1);
// sequential selection between pOp and mon
eoSequentialOp<EOT> sOp;
sOp.add(pOp, 0.9);
sOp.add(mon, 0.1);
// with one2three op
eoSequentialOp<EOT> sOp2;
sOp2.add(o2t, 1);
// sOp2.add(quad, 1);
// with three2three op
eoSequentialOp<EOT> sOp3;
sOp3.add(t2t, 1);
// eoSequentialOp<EOT> sOp3;
// sOp3.add(t2o, 1);
// sOp3.add(bin, 1);
// sOp3.add(quad, 1);
// try adding quads and bins to see what results you'll get
// now a sequential selection that is a simple "addition"
eoSequentialOp<EOT> sOpQuadPlusMon;
sOpQuadPlusMon.add(quad, 1);
sOpQuadPlusMon.add(mon, 1);
// this corresponds
eoProportionalOp<EOT> pOpSAGLike;
pOpSAGLike.add(sOpQuadPlusMon, 0.24);
pOpSAGLike.add(quad, 0.56);
pOpSAGLike.add(mon, 0.06);
pOpSAGLike.add(clone, 0.14);
// init
eoPop<EOT> pop;
eoPop<EOT> offspring;
init(pop, pSize);
// sort pop so seqPopulator is identical to SelectPopulator(SequentialSelect)
pop.sort();
std::cout << "Population initiale" << std::endl << pop << std::endl;
// To simulate SGA: first a prop between quadOp and quadClone
eoProportionalOp<EOT> pSGAOp;
pSGAOp.add(quad, 0.8);
pSGAOp.add(quadclone, 0.2);
// sequential selection between pSGAOp and mon
eoSequentialOp<EOT> virtualSGA;
virtualSGA.add(pSGAOp, 1.0);
virtualSGA.add(mon, 0.3);
eoSeqPopulator<EOT> popit(pop, offspring); // no selection, a copy of pop
// until we filled a new population
try
{
while (offspring.size() < pop.size())
{
virtualSGA(popit);
std::cout << "SeqPopulator boucle et incremente\n";
++popit;
}
}
catch(eoPopulator<EOT>::OutOfIndividuals&)
{
std::cout << "Warning: not enough individuals to handle\n";
}
std::swap(pop, offspring);
offspring.clear();
// ok, now print
std::cout << "Apres virtualSGA \n" << pop << std::endl;
init(pop, pSize);
std::cout << "=========================================================\n";
std::cout << "Now the eoSelectPopulator version !" << std::endl;
eoSequentialSelect<EOT> seqSelect;
// select.init(); should be sorted out: is it the setup method???
eoSelectivePopulator<EOT> it_step3(pop, offspring, seqSelect);
while (offspring.size() < 2*pop.size())
{
virtualSGA(it_step3);
std::cout << "SelectPopulator boucle et incremente\n";
++it_step3;
}
std::swap(pop, offspring);
offspring.clear();
// ok, now print
std::cout << "Apres SGA-like eoSelectivePopulator\n" << pop << std::endl;
std::cout << "=========================================================\n";
std::cout << "Now the pure addition !" << std::endl;
init(pop, pSize);
eoSelectivePopulator<EOT> it_step4(pop, offspring, seqSelect);
while (offspring.size() < 2*pop.size())
{
sOpQuadPlusMon(it_step4);
++it_step4;
}
std::swap(pop, offspring);
offspring.clear();
// ok, now print
std::cout << "Apres Quad+Mon ds un eoSelectivePopulator\n" << pop << std::endl;
// On teste 1->3
init(pop, pSize);
eoSelectivePopulator<EOT> it_step5(pop, offspring, seqSelect);
while (offspring.size() < 2*pop.size())
{
sOp2(it_step5);
++it_step5;
}
std::swap(pop, offspring);
offspring.clear();
// ok, now print
std::cout << "Apres 1->3 seul ds un eoSelectivePopulator\n" << pop << std::endl;
// On teste 3->3
init(pop, pSize);
eoSelectivePopulator<EOT> it_step6(pop, offspring, seqSelect);
while (offspring.size() < 2*pop.size())
{
sOp3(it_step6);
++it_step6;
}
std::swap(pop, offspring);
offspring.clear();
// ok, now print
std::cout << "Apres 3->3 seul ds un eoSelectivePopulator\n" << pop << std::endl;
return 1;
}
int main(int argc, char **argv)
{
try
{
the_main(argc, argv);
}
catch(std::exception& e)
{
std::cout << "Exception: " << e.what() << std::endl;
}
}
/*
If you want to build an SGA, you will need a copying quad op:
class quadclone : ...
{
operator(EOT& a, EOT& b)
{
// do nothing
}
}
Then the SGA operator will look like:
quadop quad;
guadclone clone;
ProportionalGenOp pOp;
pOp.add(quad, 0.8);
pOp.add(clone, 0.2); // so 80% xover rate
SequentialGenOp sOp;
sOp.add(pOp, 1,0); // always try a xover (clone 20%)
sOp.add(mut, 0.1); // low mutation rate
will result in an algorithm with:
p_xover = 0.8
p_mut = 0.1;
p_reproduction = 0.2 * 0.9 = 0.18
this does not add up to 1 because xover and mutation can be applied to a single indi
So what do you think?
*/
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