/usr/include/dune/geometry/multilineargeometry.hh is in libdune-geometry-dev 2.5.1-1.
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// vi: set et ts=4 sw=2 sts=2:
#ifndef DUNE_GEOMETRY_MULTILINEARGEOMETRY_HH
#define DUNE_GEOMETRY_MULTILINEARGEOMETRY_HH
#include <cassert>
#include <functional>
#include <iterator>
#include <limits>
#include <vector>
#include <dune/common/fmatrix.hh>
#include <dune/common/fvector.hh>
#include <dune/common/typetraits.hh>
#include <dune/geometry/affinegeometry.hh>
#include <dune/geometry/referenceelements.hh>
#include <dune/geometry/type.hh>
namespace Dune
{
// External Forward Declarations
// -----------------------------
template< class ctype, int dim >
class ReferenceElement;
template< class ctype, int dim >
struct ReferenceElements;
// MultiLinearGeometryTraits
// -------------------------
/** \brief default traits class for MultiLinearGeometry
*
* The MultiLinearGeometry (and CachedMultiLinearGeometry) allow tweaking
* some implementation details through a traits class.
*
* This structure provides the default values.
*
* \tparam ct coordinate type
*/
template< class ct >
struct MultiLinearGeometryTraits
{
/** \brief helper structure containing some matrix routines
*
* This helper allows exchanging the matrix inversion algorithms.
* It must provide the following static methods:
* \code
* template< int m, int n >
* static ctype sqrtDetAAT ( const FieldMatrix< ctype, m, n > &A );
*
* template< int m, int n >
* static ctype rightInvA ( const FieldMatrix< ctype, m, n > &A,
* FieldMatrix< ctype, n, m > &ret );
*
* template< int m, int n >
* static void xTRightInvA ( const FieldMatrix< ctype, m, n > &A,
* const FieldVector< ctype, n > &x,
* FieldVector< ctype, m > &y );
* \endcode
*/
typedef Impl::FieldMatrixHelper< ct > MatrixHelper;
/** \brief tolerance to numerical algorithms */
static ct tolerance () { return ct( 16 ) * std::numeric_limits< ct >::epsilon(); }
/** \brief template specifying the storage for the corners
*
* Internally, the MultiLinearGeometry needs to store the corners of the
* geometry.
*
* The corner storage may be chosen depending on geometry dimension and
* coordinate dimension. It is required to contain a type named Type, e.g.,
* \code
* template< int mydim, int cdim >
* struct CornerStorage
* {
* typedef std::vector< FieldVector< ctype, cdim > > Type;
* };
* \endcode
* By default, a std::vector of FieldVector is used.
*
* Apart from being copy constructable and assignable, an \c const corner
* storage object \c corners must support the expressions \c
* begin(corners), \c end(corners), and subscription \c corners[i]. \c
* begin() and \c end() are looked up via ADL and in namespace \c std:
* \code
* using std::begin;
* using std::end;
* // it is a const_iterator over the corners in Dune-ordering
* auto it = begin(corners);
* FieldVector<ctype, cdim> c0 = *it;
* auto itend = end(corners);
* while(it != itend) {
* //...
* }
*
* // elements must be accessible by subscription, indexed in
* // Dune-ordering
* FieldVector<ctype, cdim> c1 = corners[1];
* \endcode
* This means that all of the following qualify: \c
* FieldVector<ctype,cdim>[1<<mydim], \c
* std::array<FieldVector<ctype,cdim>,(1<<mydim)>, \c
* std::vector<FieldVector<ctype,cdim>>.
*
* \note The expression \c end(corners) isn't actually used by the
* implementation currently, but we require it anyway so we can add
* runtime checks for the container size when we feel like it.
*
* It is also possible to use a \c std::reference_wrapper of a suitable
* container as the type for the corner storage. The implementation
* automatically calls \c corners.get() on internally stored \c
* std::reference_wrapper objects before applying \c begin(), \c end(),
* or subscription in that case.
*
* \note Using \c std::reference_wrapper of some container as the corner
* storage means that the geometry has no control over the lifetime
* of or the access to that container. When the lifetime of the
* container ends, or the container itself or its elements are
* modified, any geometry object that still references that
* container becomes invalid. The only valid operation on invalid
* geometry objects are destruction and assignment from another
* geometry. If invalidation happens concurrently with some
* operation (other than destruction or assignment) on the
* geometry, that is a race.
*
* \tparam mydim geometry dimension
* \tparam cdim coordinate dimension
*/
template< int mydim, int cdim >
struct CornerStorage
{
typedef std::vector< FieldVector< ct, cdim > > Type;
};
/** \brief will there be only one geometry type for a dimension?
*
* If there is only a single geometry type for a certain dimension,
* <em>hasSingleGeometryType::v</em> can be set to true.
* Supporting only one geometry type might yield a gain in performance.
*
* If <em>hasSingleGeometryType::v</em> is set to true, an additional
* parameter <em>topologyId</em> is required.
* Here's an example:
* \code
* static const unsigned int topologyId = SimplexTopology< dim >::type::id;
* \endcode
*/
template< int dim >
struct hasSingleGeometryType
{
static const bool v = false;
static const unsigned int topologyId = ~0u;
};
};
// MultiLinearGeometry
// -------------------
/** \brief generic geometry implementation based on corner coordinates
*
* Based on the recursive definition of the reference elements, the
* MultiLinearGeometry provides a generic implementation of a geometry given
* the corner coordinates.
*
* The geometric mapping is multilinear in the classical sense only in the
* case of cubes; for simplices it is linear.
* The name is still justified, because the mapping satisfies the important
* property of begin linear along edges.
*
* \tparam ct coordinate type
* \tparam mydim geometry dimension
* \tparam cdim coordinate dimension
* \tparam Traits traits allowing to tweak some implementation details
* (optional)
*
* The requirements on the traits are documented along with their default,
* MultiLinearGeometryTraits.
*/
template< class ct, int mydim, int cdim, class Traits = MultiLinearGeometryTraits< ct > >
class MultiLinearGeometry
{
typedef MultiLinearGeometry< ct, mydim, cdim, Traits > This;
public:
//! coordinate type
typedef ct ctype;
//! geometry dimension
static const int mydimension= mydim;
//! coordinate dimension
static const int coorddimension = cdim;
//! type of local coordinates
typedef FieldVector< ctype, mydimension > LocalCoordinate;
//! type of global coordinates
typedef FieldVector< ctype, coorddimension > GlobalCoordinate;
//! type of jacobian transposed
typedef FieldMatrix< ctype, mydimension, coorddimension > JacobianTransposed;
//! type of jacobian inverse transposed
class JacobianInverseTransposed;
//! type of reference element
typedef Dune::ReferenceElement< ctype, mydimension > ReferenceElement;
private:
static const bool hasSingleGeometryType = Traits::template hasSingleGeometryType< mydimension >::v;
protected:
typedef typename Traits::MatrixHelper MatrixHelper;
typedef typename std::conditional< hasSingleGeometryType, std::integral_constant< unsigned int, Traits::template hasSingleGeometryType< mydimension >::topologyId >, unsigned int >::type TopologyId;
typedef Dune::ReferenceElements< ctype, mydimension > ReferenceElements;
public:
/** \brief constructor
*
* \param[in] refElement reference element for the geometry
* \param[in] corners corners to store internally
*
* \note The type of corners is actually a template argument.
* It is only required that the internal corner storage can be
* constructed from this object.
*/
template< class Corners >
MultiLinearGeometry ( const ReferenceElement &refElement,
const Corners &corners )
: refElement_( &refElement ),
corners_( corners )
{}
/** \brief constructor
*
* \param[in] gt geometry type
* \param[in] corners corners to store internally
*
* \note The type of corners is actually a template argument.
* It is only required that the internal corner storage can be
* constructed from this object.
*/
template< class Corners >
MultiLinearGeometry ( Dune::GeometryType gt,
const Corners &corners )
: refElement_( &ReferenceElements::general( gt ) ),
corners_( corners )
{}
/** \brief is this mapping affine? */
bool affine () const
{
JacobianTransposed jt;
return affine( jt );
}
/** \brief obtain the name of the reference element */
Dune::GeometryType type () const { return GeometryType( toUnsignedInt(topologyId()), mydimension ); }
/** \brief obtain number of corners of the corresponding reference element */
int corners () const { return refElement().size( mydimension ); }
/** \brief obtain coordinates of the i-th corner */
GlobalCoordinate corner ( int i ) const
{
assert( (i >= 0) && (i < corners()) );
return std::cref(corners_).get()[ i ];
}
/** \brief obtain the centroid of the mapping's image */
GlobalCoordinate center () const { return global( refElement().position( 0, 0 ) ); }
/** \brief evaluate the mapping
*
* \param[in] local local coordinate to map
*
* \returns corresponding global coordinate
*/
GlobalCoordinate global ( const LocalCoordinate &local ) const
{
using std::begin;
auto cit = begin(std::cref(corners_).get());
GlobalCoordinate y;
global< false >( topologyId(), std::integral_constant< int, mydimension >(), cit, ctype( 1 ), local, ctype( 1 ), y );
return y;
}
/** \brief evaluate the inverse mapping
*
* \param[in] globalCoord global coordinate to map
*
* \return corresponding local coordinate
*
* \note For given global coordinate y the returned local coordinate x that minimizes
* the following function over the local coordinate space spanned by the reference element.
* \code
* (global( x ) - y).two_norm()
* \endcode
*/
LocalCoordinate local ( const GlobalCoordinate &globalCoord ) const
{
const ctype tolerance = Traits::tolerance();
LocalCoordinate x = refElement().position( 0, 0 );
LocalCoordinate dx;
do
{
// Newton's method: DF^n dx^n = F^n, x^{n+1} -= dx^n
const GlobalCoordinate dglobal = (*this).global( x ) - globalCoord;
MatrixHelper::template xTRightInvA< mydimension, coorddimension >( jacobianTransposed( x ), dglobal, dx );
x -= dx;
} while( dx.two_norm2() > tolerance );
return x;
}
/** \brief obtain the integration element
*
* If the Jacobian of the mapping is denoted by $J(x)$, the integration
* integration element \f$\mu(x)\f$ is given by
* \f[ \mu(x) = \sqrt{|\det (J^T(x) J(x))|}.\f]
*
* \param[in] local local coordinate to evaluate the integration element in
*
* \returns the integration element \f$\mu(x)\f$.
*
* \note For affine mappings, it is more efficient to call
* jacobianInverseTransposed before integrationElement, if both
* are required.
*/
ctype integrationElement ( const LocalCoordinate &local ) const
{
return MatrixHelper::template sqrtDetAAT< mydimension, coorddimension >( jacobianTransposed( local ) );
}
/** \brief obtain the volume of the mapping's image
*
* \note The current implementation just returns
* \code
* integrationElement( refElement().position( 0, 0 ) ) * refElement().volume()
* \endcode
* which is wrong for n-linear surface maps and other nonlinear maps.
*/
ctype volume () const
{
return integrationElement( refElement().position( 0, 0 ) ) * refElement().volume();
}
/** \brief obtain the transposed of the Jacobian
*
* \param[in] local local coordinate to evaluate Jacobian in
*
* \returns a reference to the transposed of the Jacobian
*
* \note The returned reference is reused on the next call to
* JacobianTransposed, destroying the previous value.
*/
JacobianTransposed jacobianTransposed ( const LocalCoordinate &local ) const
{
using std::begin;
JacobianTransposed jt;
auto cit = begin(std::cref(corners_).get());
jacobianTransposed< false >( topologyId(), std::integral_constant< int, mydimension >(), cit, ctype( 1 ), local, ctype( 1 ), jt );
return jt;
}
/** \brief obtain the transposed of the Jacobian's inverse
*
* The Jacobian's inverse is defined as a pseudo-inverse. If we denote
* the Jacobian by \f$J(x)\f$, the following condition holds:
* \f[J^{-1}(x) J(x) = I.\f]
*/
JacobianInverseTransposed jacobianInverseTransposed ( const LocalCoordinate &local ) const;
friend const ReferenceElement &referenceElement ( const MultiLinearGeometry &geometry ) { return geometry.refElement(); }
protected:
const ReferenceElement &refElement () const { return *refElement_; }
TopologyId topologyId () const
{
return topologyId( std::integral_constant< bool, hasSingleGeometryType >() );
}
template< bool add, int dim, class CornerIterator >
static void global ( TopologyId topologyId, std::integral_constant< int, dim >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, GlobalCoordinate &y );
template< bool add, class CornerIterator >
static void global ( TopologyId topologyId, std::integral_constant< int, 0 >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, GlobalCoordinate &y );
template< bool add, int rows, int dim, class CornerIterator >
static void jacobianTransposed ( TopologyId topologyId, std::integral_constant< int, dim >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, FieldMatrix< ctype, rows, cdim > &jt );
template< bool add, int rows, class CornerIterator >
static void jacobianTransposed ( TopologyId topologyId, std::integral_constant< int, 0 >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, FieldMatrix< ctype, rows, cdim > &jt );
template< int dim, class CornerIterator >
static bool affine ( TopologyId topologyId, std::integral_constant< int, dim >, CornerIterator &cit, JacobianTransposed &jt );
template< class CornerIterator >
static bool affine ( TopologyId topologyId, std::integral_constant< int, 0 >, CornerIterator &cit, JacobianTransposed &jt );
bool affine ( JacobianTransposed &jacobianT ) const
{
using std::begin;
auto cit = begin(std::cref(corners_).get());
return affine( topologyId(), std::integral_constant< int, mydimension >(), cit, jacobianT );
}
private:
// The following methods are needed to convert the return type of topologyId to
// unsigned int with g++-4.4. It has problems casting integral_constant to the
// integral type.
static unsigned int toUnsignedInt(unsigned int i) { return i; }
template<unsigned int v>
static unsigned int toUnsignedInt(std::integral_constant<unsigned int,v> i) { return v; }
TopologyId topologyId ( std::integral_constant< bool, true > ) const { return TopologyId(); }
unsigned int topologyId ( std::integral_constant< bool, false > ) const { return refElement().type().id(); }
const ReferenceElement *refElement_;
typename Traits::template CornerStorage< mydimension, coorddimension >::Type corners_;
};
// MultiLinearGeometry::JacobianInverseTransposed
// ----------------------------------------------
template< class ct, int mydim, int cdim, class Traits >
class MultiLinearGeometry< ct, mydim, cdim, Traits >::JacobianInverseTransposed
: public FieldMatrix< ctype, coorddimension, mydimension >
{
typedef FieldMatrix< ctype, coorddimension, mydimension > Base;
public:
void setup ( const JacobianTransposed &jt )
{
detInv_ = MatrixHelper::template rightInvA< mydimension, coorddimension >( jt, static_cast< Base & >( *this ) );
}
void setupDeterminant ( const JacobianTransposed &jt )
{
detInv_ = MatrixHelper::template sqrtDetAAT< mydimension, coorddimension >( jt );
}
ctype det () const { return ctype( 1 ) / detInv_; }
ctype detInv () const { return detInv_; }
private:
ctype detInv_;
};
/** \brief Implement a MultiLinearGeometry with additional caching
*
* This class implements the same interface and functionality as MultiLinearGeometry.
* However, it additionally implements caching for various results.
*
* \tparam ct coordinate type
* \tparam mydim geometry dimension
* \tparam cdim coordinate dimension
* \tparam Traits traits allowing to tweak some implementation details
* (optional)
*
*/
template< class ct, int mydim, int cdim, class Traits = MultiLinearGeometryTraits< ct > >
class CachedMultiLinearGeometry
: public MultiLinearGeometry< ct, mydim, cdim, Traits >
{
typedef CachedMultiLinearGeometry< ct, mydim, cdim, Traits > This;
typedef MultiLinearGeometry< ct, mydim, cdim, Traits > Base;
protected:
typedef typename Base::MatrixHelper MatrixHelper;
public:
typedef typename Base::ReferenceElement ReferenceElement;
typedef typename Base::ctype ctype;
using Base::mydimension;
using Base::coorddimension;
typedef typename Base::LocalCoordinate LocalCoordinate;
typedef typename Base::GlobalCoordinate GlobalCoordinate;
typedef typename Base::JacobianTransposed JacobianTransposed;
typedef typename Base::JacobianInverseTransposed JacobianInverseTransposed;
template< class CornerStorage >
CachedMultiLinearGeometry ( const ReferenceElement &referenceElement, const CornerStorage &cornerStorage )
: Base( referenceElement, cornerStorage ),
affine_( Base::affine( jacobianTransposed_ ) ),
jacobianInverseTransposedComputed_( false ),
integrationElementComputed_( false )
{}
template< class CornerStorage >
CachedMultiLinearGeometry ( Dune::GeometryType gt, const CornerStorage &cornerStorage )
: Base( gt, cornerStorage ),
affine_( Base::affine( jacobianTransposed_ ) ),
jacobianInverseTransposedComputed_( false ),
integrationElementComputed_( false )
{}
/** \brief is this mapping affine? */
bool affine () const { return affine_; }
using Base::corner;
/** \brief obtain the centroid of the mapping's image */
GlobalCoordinate center () const { return global( refElement().position( 0, 0 ) ); }
/** \brief evaluate the mapping
*
* \param[in] local local coordinate to map
*
* \returns corresponding global coordinate
*/
GlobalCoordinate global ( const LocalCoordinate &local ) const
{
if( affine() )
{
GlobalCoordinate global( corner( 0 ) );
jacobianTransposed_.umtv( local, global );
return global;
}
else
return Base::global( local );
}
/** \brief evaluate the inverse mapping
*
* \param[in] global global coordinate to map
*
* \return corresponding local coordinate
*
* \note For given global coordinate y the returned local coordinate x that minimizes
* the following function over the local coordinate space spanned by the reference element.
* \code
* (global( x ) - y).two_norm()
* \endcode
*/
LocalCoordinate local ( const GlobalCoordinate &global ) const
{
if( affine() )
{
LocalCoordinate local;
if( jacobianInverseTransposedComputed_ )
jacobianInverseTransposed_.mtv( global - corner( 0 ), local );
else
MatrixHelper::template xTRightInvA< mydimension, coorddimension >( jacobianTransposed_, global - corner( 0 ), local );
return local;
}
else
return Base::local( global );
}
/** \brief obtain the integration element
*
* If the Jacobian of the mapping is denoted by $J(x)$, the integration
* integration element \f$\mu(x)\f$ is given by
* \f[ \mu(x) = \sqrt{|\det (J^T(x) J(x))|}.\f]
*
* \param[in] local local coordinate to evaluate the integration element in
*
* \returns the integration element \f$\mu(x)\f$.
*
* \note For affine mappings, it is more efficient to call
* jacobianInverseTransposed before integrationElement, if both
* are required.
*/
ctype integrationElement ( const LocalCoordinate &local ) const
{
if( affine() )
{
if( !integrationElementComputed_ )
{
jacobianInverseTransposed_.setupDeterminant( jacobianTransposed_ );
integrationElementComputed_ = true;
}
return jacobianInverseTransposed_.detInv();
}
else
return Base::integrationElement( local );
}
/** \brief obtain the volume of the mapping's image */
ctype volume () const
{
if( affine() )
return integrationElement( refElement().position( 0, 0 ) ) * refElement().volume();
else
return Base::volume();
}
/** \brief obtain the transposed of the Jacobian
*
* \param[in] local local coordinate to evaluate Jacobian in
*
* \returns a reference to the transposed of the Jacobian
*
* \note The returned reference is reused on the next call to
* JacobianTransposed, destroying the previous value.
*/
JacobianTransposed jacobianTransposed ( const LocalCoordinate &local ) const
{
if( affine() )
return jacobianTransposed_;
else
return Base::jacobianTransposed( local );
}
/** \brief obtain the transposed of the Jacobian's inverse
*
* The Jacobian's inverse is defined as a pseudo-inverse. If we denote
* the Jacobian by \f$J(x)\f$, the following condition holds:
* \f[J^{-1}(x) J(x) = I.\f]
*/
JacobianInverseTransposed jacobianInverseTransposed ( const LocalCoordinate &local ) const
{
if( affine() )
{
if( !jacobianInverseTransposedComputed_ )
{
jacobianInverseTransposed_.setup( jacobianTransposed_ );
jacobianInverseTransposedComputed_ = true;
integrationElementComputed_ = true;
}
return jacobianInverseTransposed_;
}
else
return Base::jacobianInverseTransposed( local );
}
protected:
using Base::refElement;
private:
mutable JacobianTransposed jacobianTransposed_;
mutable JacobianInverseTransposed jacobianInverseTransposed_;
mutable bool affine_ : 1;
mutable bool jacobianInverseTransposedComputed_ : 1;
mutable bool integrationElementComputed_ : 1;
};
// Implementation of MultiLinearGeometry
// -------------------------------------
template< class ct, int mydim, int cdim, class Traits >
inline typename MultiLinearGeometry< ct, mydim, cdim, Traits >::JacobianInverseTransposed
MultiLinearGeometry< ct, mydim, cdim, Traits >::jacobianInverseTransposed ( const LocalCoordinate &local ) const
{
JacobianInverseTransposed jit;
jit.setup( jacobianTransposed( local ) );
return jit;
}
template< class ct, int mydim, int cdim, class Traits >
template< bool add, int dim, class CornerIterator >
inline void MultiLinearGeometry< ct, mydim, cdim, Traits >
::global ( TopologyId topologyId, std::integral_constant< int, dim >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, GlobalCoordinate &y )
{
const ctype xn = df*x[ dim-1 ];
const ctype cxn = ctype( 1 ) - xn;
if( Impl::isPrism( toUnsignedInt(topologyId), mydimension, mydimension-dim ) )
{
// apply (1-xn) times mapping for bottom
global< add >( topologyId, std::integral_constant< int, dim-1 >(), cit, df, x, rf*cxn, y );
// apply xn times mapping for top
global< true >( topologyId, std::integral_constant< int, dim-1 >(), cit, df, x, rf*xn, y );
}
else
{
assert( Impl::isPyramid( toUnsignedInt(topologyId), mydimension, mydimension-dim ) );
// apply (1-xn) times mapping for bottom (with argument x/(1-xn))
if( cxn > Traits::tolerance() || cxn < -Traits::tolerance() )
global< add >( topologyId, std::integral_constant< int, dim-1 >(), cit, df/cxn, x, rf*cxn, y );
else
global< add >( topologyId, std::integral_constant< int, dim-1 >(), cit, df, x, ctype( 0 ), y );
// apply xn times the tip
y.axpy( rf*xn, *cit );
++cit;
}
}
template< class ct, int mydim, int cdim, class Traits >
template< bool add, class CornerIterator >
inline void MultiLinearGeometry< ct, mydim, cdim, Traits >
::global ( TopologyId topologyId, std::integral_constant< int, 0 >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, GlobalCoordinate &y )
{
const GlobalCoordinate &origin = *cit;
++cit;
for( int i = 0; i < coorddimension; ++i )
y[ i ] = (add ? y[ i ] + rf*origin[ i ] : rf*origin[ i ]);
}
template< class ct, int mydim, int cdim, class Traits >
template< bool add, int rows, int dim, class CornerIterator >
inline void MultiLinearGeometry< ct, mydim, cdim, Traits >
::jacobianTransposed ( TopologyId topologyId, std::integral_constant< int, dim >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, FieldMatrix< ctype, rows, cdim > &jt )
{
assert( rows >= dim );
const ctype xn = df*x[ dim-1 ];
const ctype cxn = ctype( 1 ) - xn;
auto cit2( cit );
if( Impl::isPrism( toUnsignedInt(topologyId), mydimension, mydimension-dim ) )
{
// apply (1-xn) times Jacobian for bottom
jacobianTransposed< add >( topologyId, std::integral_constant< int, dim-1 >(), cit2, df, x, rf*cxn, jt );
// apply xn times Jacobian for top
jacobianTransposed< true >( topologyId, std::integral_constant< int, dim-1 >(), cit2, df, x, rf*xn, jt );
// compute last row as difference between top value and bottom value
global< add >( topologyId, std::integral_constant< int, dim-1 >(), cit, df, x, -rf, jt[ dim-1 ] );
global< true >( topologyId, std::integral_constant< int, dim-1 >(), cit, df, x, rf, jt[ dim-1 ] );
}
else
{
assert( Impl::isPyramid( toUnsignedInt(topologyId), mydimension, mydimension-dim ) );
/*
* In the pyramid case, we need a transformation Tb: B -> R^n for the
* base B \subset R^{n-1}. The pyramid transformation is then defined as
* T: P \subset R^n -> R^n
* (x, xn) |-> (1-xn) Tb(x*) + xn t (x \in R^{n-1}, xn \in R)
* with the tip of the pyramid mapped to t and x* = x/(1-xn)
* the projection of (x,xn) onto the base.
*
* For the Jacobi matrix DT we get
* DT = ( A | b )
* with A = DTb(x*) (n x n-1 matrix)
* and b = dT/dxn (n-dim column vector).
* Furthermore
* b = -Tb(x*) + t + \sum_i dTb/dx_i(x^*) x_i/(1-xn)
*
* Note that both A and b are not defined in the pyramid tip (x=0, xn=1)!
* Indeed for B the unit square, Tb mapping B to the quadrilateral given
* by the vertices (0,0,0), (2,0,0), (0,1,0), (1,1,0) and t=(0,0,1), we get
*
* T(x,y,xn) = ( x(2-y/(1-xn)), y, xn )
* / 2-y/(1-xn) -x 0 \
* DT(x,y,xn) = | 0 1 0 |
* \ 0 0 1 /
* which is not continuous for xn -> 1, choose for example
* x=0, y=1-xn, xn -> 1 --> DT -> diag(1,1,1)
* x=1-xn, y=0, xn -> 1 --> DT -> diag(2,1,1)
*
* However, for Tb affine-linear, Tb(y) = My + y0, DTb = M:
* A = M
* b = -M x* - y0 + t + \sum_i M_i x_i/(1-xn)
* = -M x* - y0 + t + M x*
* = -y0 + t
* which is continuous for xn -> 1. Note that this b is also given by
* b = -Tb(0) + t + \sum_i dTb/dx_i(0) x_i/1
* that is replacing x* by 1 and 1-xn by 1 in the formular above.
*
* For xn -> 1, we can thus set x*=0, "1-xn"=1 (or anything != 0) and get
* the right result in case Tb is affine-linear.
*/
/* The second case effectively results in x* = 0 */
ctype dfcxn = (cxn > Traits::tolerance() || cxn < -Traits::tolerance()) ? ctype(df / cxn) : ctype(0);
// initialize last row
// b = -Tb(x*)
// (b = -Tb(0) = -y0 in case xn -> 1 and Tb affine-linear)
global< add >( topologyId, std::integral_constant< int, dim-1 >(), cit, dfcxn, x, -rf, jt[ dim-1 ] );
// b += t
jt[ dim-1 ].axpy( rf, *cit );
++cit;
// apply Jacobian for bottom (with argument x/(1-xn)) and correct last row
if( add )
{
FieldMatrix< ctype, dim-1, coorddimension > jt2;
// jt2 = dTb/dx_i(x*)
jacobianTransposed< false >( topologyId, std::integral_constant< int, dim-1 >(), cit2, dfcxn, x, rf, jt2 );
// A = dTb/dx_i(x*) (jt[j], j=0..dim-1)
// b += \sum_i dTb/dx_i(x*) x_i/(1-xn) (jt[dim-1])
// (b += 0 in case xn -> 1)
for( int j = 0; j < dim-1; ++j )
{
jt[ j ] += jt2[ j ];
jt[ dim-1 ].axpy( dfcxn*x[ j ], jt2[ j ] );
}
}
else
{
// jt = dTb/dx_i(x*)
jacobianTransposed< false >( topologyId, std::integral_constant< int, dim-1 >(), cit2, dfcxn, x, rf, jt );
// b += \sum_i dTb/dx_i(x*) x_i/(1-xn)
for( int j = 0; j < dim-1; ++j )
jt[ dim-1 ].axpy( dfcxn*x[ j ], jt[ j ] );
}
}
}
template< class ct, int mydim, int cdim, class Traits >
template< bool add, int rows, class CornerIterator >
inline void MultiLinearGeometry< ct, mydim, cdim, Traits >
::jacobianTransposed ( TopologyId topologyId, std::integral_constant< int, 0 >,
CornerIterator &cit, const ctype &df, const LocalCoordinate &x,
const ctype &rf, FieldMatrix< ctype, rows, cdim > &jt )
{
++cit;
}
template< class ct, int mydim, int cdim, class Traits >
template< int dim, class CornerIterator >
inline bool MultiLinearGeometry< ct, mydim, cdim, Traits >
::affine ( TopologyId topologyId, std::integral_constant< int, dim >, CornerIterator &cit, JacobianTransposed &jt )
{
const GlobalCoordinate &orgBottom = *cit;
if( !affine( topologyId, std::integral_constant< int, dim-1 >(), cit, jt ) )
return false;
const GlobalCoordinate &orgTop = *cit;
if( Impl::isPrism( toUnsignedInt(topologyId), mydimension, mydimension-dim ) )
{
JacobianTransposed jtTop;
if( !affine( topologyId, std::integral_constant< int, dim-1 >(), cit, jtTop ) )
return false;
// check whether both jacobians are identical
ctype norm( 0 );
for( int i = 0; i < dim-1; ++i )
norm += (jtTop[ i ] - jt[ i ]).two_norm2();
if( norm >= Traits::tolerance() )
return false;
}
else
++cit;
jt[ dim-1 ] = orgTop - orgBottom;
return true;
}
template< class ct, int mydim, int cdim, class Traits >
template< class CornerIterator >
inline bool MultiLinearGeometry< ct, mydim, cdim, Traits >
::affine ( TopologyId topologyId, std::integral_constant< int, 0 >, CornerIterator &cit, JacobianTransposed &jt )
{
++cit;
return true;
}
} // namespace Dune
#endif // #ifndef DUNE_GEOMETRY_MULTILINEARGEOMETRY_HH
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