DUNE PDELab (2.7)

// -*- tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*-
// vi: set et ts=8 sw=2 sts=2:
 
#ifndef DUNE_PDELAB_FUNCTION_CALLABLEADAPTER_HH
#define DUNE_PDELAB_FUNCTION_CALLABLEADAPTER_HH
 
#include <utility>
#include <type_traits>
#include <dune/common/fvector.hh>
#include <dune/common/typetraits.hh>
 
#include <dune/pdelab/common/function.hh>
#include <dune/pdelab/constraints/common/constraintsparameters.hh>
 
namespace Dune {
  namespace PDELab {
 
    /************************
     * Grid function adapters
     ************************/
 
    template<typename GV, typename RF, int n, typename F>
    class GlobalCallableToGridFunctionAdapter
      : public Dune::PDELab::GridFunctionBase<Dune::PDELab::
                                              GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> >,
                                              GlobalCallableToGridFunctionAdapter<GV,RF,n,F> >
    {
      GV gv;
      F f;
    public:
      typedef Dune::PDELab::
      GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> > Traits;
 
      GlobalCallableToGridFunctionAdapter (const GV& gv_, const F& f_) : gv(gv_), f(f_) {}
 
      inline const GV& getGridView () const {return gv;}
 
      inline void evaluate (const typename Traits::ElementType& e,
                            const typename Traits::DomainType& xl,
                            typename Traits::RangeType& y) const
      {
        typename Traits::DomainType xg = e.geometry().global(xl);
        y = f(xg);
      }
    };
 
    template<typename T>
    struct CallableAdapterGetDim {
      enum {dim=1};
    };
 
    template<typename T, int n>
    struct CallableAdapterGetDim< FieldVector<T,n> > {
      enum {dim=n};
    };
 
    template<typename T>
    struct CallableAdapterGetRangeFieldType {
      typedef T Type;
    };
 
    template<typename T, int n>
    struct CallableAdapterGetRangeFieldType< FieldVector<T,n> > {
      typedef T Type;
    };
 
 
    template<typename GV, typename RF, int n, typename F>
    class LocalCallableToGridFunctionAdapter
      : public Dune::PDELab::GridFunctionBase<Dune::PDELab::
                                              GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> >,
                                              LocalCallableToGridFunctionAdapter<GV,RF,n,F> >
    {
      GV gv;
      F f;
    public:
      typedef Dune::PDELab::
      GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> > Traits;
 
      LocalCallableToGridFunctionAdapter (const GV& gv_, const F& f_) : gv(gv_), f(f_) {}
 
      inline const GV& getGridView () const {return gv;}
 
      inline void evaluate (const typename Traits::ElementType& e,
                            const typename Traits::DomainType& xl,
                            typename Traits::RangeType& y) const
      {
        y = f(e,xl);
      }
    };
 
#ifdef DOXYGEN
 
    template <typename GV, typename F>
    WrapperConformingToGridFunctionInterface makeGridFunctionFromCallable (const GV& gv, const F& f)
    {}
#endif
 
#ifndef DOXYGEN
    template <typename GV, typename F>
    auto makeGridFunctionFromCallable (const GV& gv, const F& f)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
          >::value,
        GlobalCallableToGridFunctionAdapter<
          GV,
          typename CallableAdapterGetRangeFieldType<
            decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
            >::Type,
          CallableAdapterGetDim<
            decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
            >::dim,
          F>
        >::type
    {
      typedef typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate X;
      X x;
      typedef decltype(f(x)) ReturnType;
      typedef typename CallableAdapterGetRangeFieldType<ReturnType>::Type RF;
      const int dim = CallableAdapterGetDim<ReturnType>::dim;
      typedef GlobalCallableToGridFunctionAdapter<GV,RF,dim,F> TheType;
      return TheType(gv,f);
    }
 
    template <typename GV, typename F>
    auto makeGridFunctionFromCallable (const GV& gv, const F& f)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(
                     std::declval<typename GV::template Codim<0>::Entity>(),
                     std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                     ))
          >::value,
        LocalCallableToGridFunctionAdapter<
          GV,
          typename CallableAdapterGetRangeFieldType<
            decltype(f(
                       std::declval<typename GV::template Codim<0>::Entity>(),
                       std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                       ))
            >::Type,
          CallableAdapterGetDim<
            decltype(f(
                       std::declval<typename GV::template Codim<0>::Entity>(),
                       std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                       ))
            >::dim,
          F>
        >::type
    {
      typedef typename GV::template Codim<0>::Entity E;
      E e;
      typedef typename E::Geometry::LocalCoordinate X;
      X x;
      typedef decltype(f(e,x)) ReturnType;
      typedef typename CallableAdapterGetRangeFieldType<ReturnType>::Type RF;
      const int dim = CallableAdapterGetDim<ReturnType>::dim;
      typedef LocalCallableToGridFunctionAdapter<GV,RF,dim,F> TheType;
      return TheType(gv,f);
    }
#endif // DOXYGEN
 
 
    /*************************************
     * Instationary grid function adapters
     *************************************/
 
 
    template<typename GV, typename RF, int n, typename F, typename P>
    class GlobalCallableToInstationaryGridFunctionAdapter
      : public Dune::PDELab::GridFunctionBase<Dune::PDELab::
                                              GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> >,
                                              GlobalCallableToInstationaryGridFunctionAdapter<GV,RF,n,F,P> >
    {
      GV gv;
      F f;
      P& p;
    public:
      typedef Dune::PDELab::
      GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> > Traits;
 
      GlobalCallableToInstationaryGridFunctionAdapter (const GV& gv_, const F& f_, P& p_)
        : gv(gv_), f(f_), p(p_)
      {}
 
      inline const GV& getGridView () const {return gv;}
 
      inline void evaluate (const typename Traits::ElementType& e,
                            const typename Traits::DomainType& xl,
                            typename Traits::RangeType& y) const
      {
        typename Traits::DomainType xg = e.geometry().global(xl);
        y = f(xg);
      }
 
      // pass time to parameter object
      void setTime (RF t) {
        p.setTime(t);
      }
    };
 
    template<typename GV, typename RF, int n, typename F, typename P>
    class LocalCallableToInstationaryGridFunctionAdapter
      : public Dune::PDELab::GridFunctionBase<Dune::PDELab::
                                              GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> >,
                                              LocalCallableToInstationaryGridFunctionAdapter<GV,RF,n,F,P> >
    {
      GV gv;
      F f;
      P& p;
    public:
      typedef Dune::PDELab::
      GridFunctionTraits<GV,RF,n,Dune::FieldVector<RF,n> > Traits;
 
      LocalCallableToInstationaryGridFunctionAdapter (const GV& gv_, const F& f_, P& p_) : gv(gv_), f(f_), p(p_) {}
 
      inline const GV& getGridView () const {return gv;}
 
      inline void evaluate (const typename Traits::ElementType& e,
                            const typename Traits::DomainType& xl,
                            typename Traits::RangeType& y) const
      {
        y = f(e,xl);
      }
 
      // pass time to parameter object
      void setTime (RF t) {
        p.setTime(t);
      }
    };
 
#ifdef DOXYGEN
 
    template <typename GV, typename F>
    WrapperConformingToGridFunctionInterface makeInstationaryGridFunctionFromCallable (const GV& gv, const F& f)
    {}
#endif
 
#ifndef DOXYGEN
    template <typename GV, typename F, typename PARAM>
    auto makeInstationaryGridFunctionFromCallable (const GV& gv, const F& f, PARAM& param)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
          >::value,
        GlobalCallableToInstationaryGridFunctionAdapter<
          GV,
          typename CallableAdapterGetRangeFieldType<
            decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
            >::Type,
          CallableAdapterGetDim<
            decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
            >::dim,
          F,
          PARAM>
        >::type
    {
      typedef typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate X;
      X x;
      typedef decltype(f(x)) ReturnType;
      typedef typename CallableAdapterGetRangeFieldType<ReturnType>::Type RF;
      const int dim = CallableAdapterGetDim<ReturnType>::dim;
      typedef GlobalCallableToInstationaryGridFunctionAdapter<GV,RF,dim,F,PARAM> TheType;
      return TheType(gv,f,param);
    }
 
    template <typename GV, typename F, typename PARAM>
    auto makeInstationaryGridFunctionFromCallable (const GV& gv, const F& f, PARAM& param)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(
                     std::declval<typename GV::template Codim<0>::Entity>(),
                     std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                     ))
          >::value,
        LocalCallableToInstationaryGridFunctionAdapter<
          GV,
          typename CallableAdapterGetRangeFieldType<
            decltype(f(
                       std::declval<typename GV::template Codim<0>::Entity>(),
                       std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                       ))
            >::Type,
          CallableAdapterGetDim<
            decltype(f(
                       std::declval<typename GV::template Codim<0>::Entity>(),
                       std::declval<typename GV::template Codim<0>::Entity::Geometry::LocalCoordinate>()
                       ))
            >::dim,
          F,
          PARAM>
        >::type
    {
      typedef typename GV::template Codim<0>::Entity E;
      E e;
      typedef typename E::Geometry::LocalCoordinate X;
      X x;
      typedef decltype(f(e,x)) ReturnType;
      typedef typename CallableAdapterGetRangeFieldType<ReturnType>::Type RF;
      const int dim = CallableAdapterGetDim<ReturnType>::dim;
      typedef LocalCallableToInstationaryGridFunctionAdapter<GV,RF,dim,F,PARAM> TheType;
      return TheType(gv,f,param);
    }
#endif // DOXYGEN
 
 
    /*****************************
     * Boundary condition adapters
     *****************************/
 
    template<typename F>
    class GlobalCallableToBoundaryConditionAdapter
      : public Dune::PDELab::DirichletConstraintsParameters
    {
      F f;
 
    public:
      GlobalCallableToBoundaryConditionAdapter (F f_) : f(f_) {}
 
      template<typename I>
      bool isDirichlet(const I & intersection,
                       const Dune::FieldVector<typename I::ctype, I::mydimension> & coord
                       ) const
      {
        auto xg = intersection.geometry().global(coord);
        return f(xg);
      }
 
      template<typename I>
      bool isNeumann(const I & ig,
                     const Dune::FieldVector<typename I::ctype, I::mydimension> & coord
                     ) const
      {
        return !isDirichlet( ig, coord );
      }
 
    };
 
    template<typename F>
    class LocalCallableToBoundaryConditionAdapter :
      public Dune::PDELab::FluxConstraintsParameters,
      public Dune::PDELab::DirichletConstraintsParameters
    {
      const F f;
 
    public:
 
      LocalCallableToBoundaryConditionAdapter(const F& f_ )
        : f( f_ )
      {}
 
      template<typename I>
      bool isDirichlet(const I & ig, const Dune::FieldVector<typename I::ctype, I::mydimension> & coord
                       ) const
      {
        return(f(ig.intersection(),coord));
      }
 
      template<typename I>
      bool isNeumann(const I & ig,
                     const Dune::FieldVector<typename I::ctype, I::mydimension> & coord
                     ) const
      {
        return !isDirichlet( ig, coord );
      }
    };
 
#ifdef DOXYGEN
 
    template <typename GV, typename F>
    BoundaryConditionAdapter makebBoundaryConditionFromCallable (const GV& gv, const F& f)
#endif
 
#ifndef DOXYGEN
    template<typename GV, typename F>
    auto makeBoundaryConditionFromCallable (const GV& gv, const F& f)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(std::declval<typename GV::template Codim<0>::Entity::Geometry::GlobalCoordinate>()))
          >::value,
        GlobalCallableToBoundaryConditionAdapter<F>
        >::type
    {
      return GlobalCallableToBoundaryConditionAdapter<F>(f);
    }
 
    template<typename GV, typename F>
    auto makeBoundaryConditionFromCallable (const GV& gv, const F& f)
      -> typename std::enable_if<
        AlwaysTrue <
          decltype(f(std::declval<typename GV::Intersection>(),
                     std::declval<typename GV::Intersection::Geometry::LocalCoordinate>()
                     ))
        >::value
      ,
        LocalCallableToBoundaryConditionAdapter<F>
        >::type
    {
      return LocalCallableToBoundaryConditionAdapter<F>(f);
    }
#endif
 
 
  }
}
#endif // DUNE_PDELAB_FUNCTION_CALLABLEADAPTER_HH
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