Move the hyper volume dual difference metric in a separated file

moeo/src/metric/moeoDualHyperVolumeDifferenceMetric.h

@@ -0,0 +1,117 @@
+/*
+
+(c) 2013 Thales group
+
+    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; version 2
+    of the License.
+
+    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: http://eodev.sourceforge.net
+
+Authors:
+    Johann Dréo <johann.dreo@thalesgroup.com>
+
+*/
+
+#ifndef MOEODUALHYPERVOLUMEDIFFERENCEMETRIC_H_
+#define MOEODUALHYPERVOLUMEDIFFERENCEMETRIC_H_
+
+#include <metric/moeoHyperVolumeDifferenceMetric.h>
+
+
+template<class ObjectiveVector>
+class moeoDualHyperVolumeDifferenceMetric : public moeoHyperVolumeDifferenceMetric<ObjectiveVector>
+{
+protected:
+    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::rho;
+    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::normalize;
+    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::ref_point;
+    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::bounds;
+
+public:
+
+    typedef typename ObjectiveVector::Type Type;
+
+    moeoDualHyperVolumeDifferenceMetric( bool _normalize=true, double _rho=1.1)
+        : moeoHyperVolumeDifferenceMetric<ObjectiveVector>(_normalize, _rho)
+    {
+
+    }
+
+    moeoDualHyperVolumeDifferenceMetric( bool _normalize/*=true*/, ObjectiveVector& _ref_point/*=NULL*/ )
+        : moeoHyperVolumeDifferenceMetric<ObjectiveVector>( _normalize, _ref_point )
+    {
+
+    }
+
+    /**
+     * calculates and returns the HyperVolume value of a pareto front
+     * @param _set1 the vector contains all objective Vector of the first pareto front
+     * @param _set2 the vector contains all objective Vector of the second pareto front
+     */
+    virtual double operator()(const std::vector < ObjectiveVector > & _set1, const std::vector < ObjectiveVector > & _set2)
+    {
+#ifndef NDEBUG
+        // the two sets must be homogeneous in feasibility
+        assert( _set1.size() > 0 );
+        for( unsigned int i=1; i<_set1.size(); ++i ) {
+            assert( _set1[i].is_feasible() == _set1[0].is_feasible() );
+        }
+        assert( _set2.size() > 0 );
+        for( unsigned int i=1; i<_set2.size(); ++i ) {
+            assert( _set2[i].is_feasible() == _set2[0].is_feasible() );
+        }
+        // and they must have the same feasibility
+        assert( _set1[0].is_feasible() == _set2[0].is_feasible() );
+#endif
+        bool feasible = _set1[0].is_feasible();
+
+        double hypervolume_set1;
+        double hypervolume_set2;
+
+        if(rho >= 1.0){
+            //determine bounds
+            setup(_set1, _set2);
+            //determine reference point
+            for (unsigned int i=0; i<ObjectiveVector::Traits::nObjectives(); i++){
+                if(normalize){
+                    if (ObjectiveVector::Traits::minimizing(i))
+                        ref_point[i]= Type(rho, feasible);
+                    else
+                        ref_point[i]= Type(1-rho, feasible);
+                }
+                else{
+                    if (ObjectiveVector::Traits::minimizing(i))
+                        ref_point[i]= Type(bounds[i].maximum() * rho, feasible);
+                    else
+                        ref_point[i]= Type(bounds[i].maximum() * (1-rho), feasible);
+                }
+            }
+            //if no normalization, reinit bounds to O..1 for
+            if(!normalize)
+                for (unsigned int i=0; i<ObjectiveVector::Traits::nObjectives(); i++)
+                    bounds[i] = eoRealInterval(0,1);
+
+        }
+        else if(normalize)
+            setup(_set1, _set2);
+
+        moeoHyperVolumeMetric <ObjectiveVector> unaryMetric(ref_point, bounds);
+        hypervolume_set1 = unaryMetric(_set1);
+        hypervolume_set2 = unaryMetric(_set2);
+
+        return hypervolume_set1 - hypervolume_set2;
+    }
+};
+
+#endif /*MOEODUALHYPERVOLUMEDIFFERENCEMETRIC_H_*/

moeo/src/metric/moeoHyperVolumeDifferenceMetric.h

@@ -197,90 +197,4 @@ class moeoHyperVolumeDifferenceMetric : public moeoVectorVsVectorBinaryMetric <
 
   };
 
-
-template<class ObjectiveVector>
-class moeoDualHyperVolumeDifferenceMetric : public moeoHyperVolumeDifferenceMetric<ObjectiveVector>
-{
-protected:
-    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::rho;
-    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::normalize;
-    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::ref_point;
-    using moeoHyperVolumeDifferenceMetric<ObjectiveVector>::bounds;
-
-public:
-
-    typedef typename ObjectiveVector::Type Type;
-
-    moeoDualHyperVolumeDifferenceMetric( bool _normalize=true, double _rho=1.1)
-        : moeoHyperVolumeDifferenceMetric<ObjectiveVector>(_normalize, _rho)
-    {
-
-    }
-
-    moeoDualHyperVolumeDifferenceMetric( bool _normalize/*=true*/, ObjectiveVector& _ref_point/*=NULL*/ )
-        : moeoHyperVolumeDifferenceMetric<ObjectiveVector>( _normalize, _ref_point )
-    {
-
-    }
-
-    /**
-     * calculates and returns the HyperVolume value of a pareto front
-     * @param _set1 the vector contains all objective Vector of the first pareto front
-     * @param _set2 the vector contains all objective Vector of the second pareto front
-     */
-    virtual double operator()(const std::vector < ObjectiveVector > & _set1, const std::vector < ObjectiveVector > & _set2)
-    {
-#ifndef NDEBUG
-        // the two sets must be homogeneous in feasibility
-        assert( _set1.size() > 0 );
-        for( unsigned int i=1; i<_set1.size(); ++i ) {
-            assert( _set1[i].is_feasible() == _set1[0].is_feasible() );
-        }
-        assert( _set2.size() > 0 );
-        for( unsigned int i=1; i<_set2.size(); ++i ) {
-            assert( _set2[i].is_feasible() == _set2[0].is_feasible() );
-        }
-        // and they must have the same feasibility
-        assert( _set1[0].is_feasible() == _set2[0].is_feasible() );
-#endif
-        bool feasible = _set1[0].is_feasible();
-
-        double hypervolume_set1;
-        double hypervolume_set2;
-
-        if(rho >= 1.0){
-            //determine bounds
-            setup(_set1, _set2);
-            //determine reference point
-            for (unsigned int i=0; i<ObjectiveVector::Traits::nObjectives(); i++){
-                if(normalize){
-                    if (ObjectiveVector::Traits::minimizing(i))
-                        ref_point[i]= Type(rho, feasible);
-                    else
-                        ref_point[i]= Type(1-rho, feasible);
-                }
-                else{
-                    if (ObjectiveVector::Traits::minimizing(i))
-                        ref_point[i]= Type(bounds[i].maximum() * rho, feasible);
-                    else
-                        ref_point[i]= Type(bounds[i].maximum() * (1-rho), feasible);
-                }
-            }
-            //if no normalization, reinit bounds to O..1 for
-            if(!normalize)
-                for (unsigned int i=0; i<ObjectiveVector::Traits::nObjectives(); i++)
-                    bounds[i] = eoRealInterval(0,1);
-
-        }
-        else if(normalize)
-            setup(_set1, _set2);
-
-        moeoHyperVolumeMetric <ObjectiveVector> unaryMetric(ref_point, bounds);
-        hypervolume_set1 = unaryMetric(_set1);
-        hypervolume_set2 = unaryMetric(_set2);
-
-        return hypervolume_set1 - hypervolume_set2;
-    }
-};
-
 #endif /*MOEOHYPERVOLUMEMETRIC_H_*/