doc/html/Thyra__DefaultMultiVectorProductVector__def_8hpp_source.html

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 #ifndef THYRA_DEFAULT_MULTI_VECTOR_PRODUCT_VECTOR_HPP
 #define THYRA_DEFAULT_MULTI_VECTOR_PRODUCT_VECTOR_HPP


 #include "Thyra_DefaultMultiVectorProductVector_decl.hpp"
 #include "Thyra_DefaultMultiVectorProductVectorSpace.hpp"
 #include "Thyra_AssertOp.hpp"
 #include "Teuchos_Assert.hpp"


 namespace Thyra {


 // Constructors/initializers/accessors


 template <class Scalar>
 DefaultMultiVectorProductVector<Scalar>::DefaultMultiVectorProductVector()
 {
   uninitialize();
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::initialize(
   const RCP<const DefaultMultiVectorProductVectorSpace<Scalar> > &productSpace_in,
   const RCP<MultiVectorBase<Scalar> > &multiVec
   )
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_TEST_FOR_EXCEPT(is_null(productSpace_in));
   TEUCHOS_TEST_FOR_EXCEPT(is_null(multiVec));
   THYRA_ASSERT_VEC_SPACES(
     "DefaultMultiVectorProductVector<Scalar>::initialize(productSpace,multiVec)",
     *multiVec->range(), *productSpace_in->getBlock(0)
     );
   TEUCHOS_ASSERT_EQUALITY( multiVec->domain()->dim(), productSpace_in->numBlocks());
 #endif

   numBlocks_ = productSpace_in->numBlocks();

   productSpace_ = productSpace_in;

   multiVec_ = multiVec;

 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::initialize(
   const RCP<const DefaultMultiVectorProductVectorSpace<Scalar> > &productSpace_in,
   const RCP<const MultiVectorBase<Scalar> > &multiVec
   )
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_TEST_FOR_EXCEPT(is_null(productSpace_in));
   TEUCHOS_TEST_FOR_EXCEPT(is_null(multiVec));
   THYRA_ASSERT_VEC_SPACES(
     "DefaultMultiVectorProductVector<Scalar>::initialize(productSpace_in,multiVec)",
     *multiVec->range(), *productSpace_in->getBlock(0)
     );
   TEUCHOS_ASSERT_EQUALITY( multiVec->domain()->dim(), productSpace_in->numBlocks() );
 #endif

   numBlocks_ = productSpace_in->numBlocks();

   productSpace_ = productSpace_in;

   multiVec_ = multiVec;

 }


 template <class Scalar>
 RCP<MultiVectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getNonconstMultiVector()
 {
   return multiVec_.getNonconstObj();
 }


 template <class Scalar>
 RCP<const MultiVectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getMultiVector() const
 {
   return multiVec_.getConstObj();
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::uninitialize()
 {
   numBlocks_ = 0;
   productSpace_ = Teuchos::null;
   multiVec_.uninitialize();
 }


 // Overridden from Teuchos::Describable


 template<class Scalar>
 std::string DefaultMultiVectorProductVector<Scalar>::description() const
 {
   std::ostringstream oss;
   oss
     << Teuchos::Describable::description()
     << "{"
     << "dim="<<this->space()->dim()
     << ",numColumns = "<<numBlocks_
     << "}";
   return oss.str();
 }

 template<class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::describe(
   Teuchos::FancyOStream &out_arg,
   const Teuchos::EVerbosityLevel verbLevel
   ) const
 {
   using Teuchos::OSTab;
   using Teuchos::describe;
   RCP<FancyOStream> out = rcp(&out_arg,false);
   OSTab tab(out);
   switch(verbLevel) {
     case Teuchos::VERB_DEFAULT:
     case Teuchos::VERB_LOW:
       *out << this->description() << std::endl;
       break;
     case Teuchos::VERB_MEDIUM:
     case Teuchos::VERB_HIGH:
     case Teuchos::VERB_EXTREME:
     {
       *out
         << Teuchos::Describable::description() << "{"
         << "dim=" << this->space()->dim()
         << "}\n";
       OSTab tab2(out);
       *out <<  "multiVec = " << Teuchos::describe(*multiVec_.getConstObj(),verbLevel);
       break;
     }
     default:
       TEUCHOS_TEST_FOR_EXCEPT(true); // Should never get here!
   }
 }


 // Overridden from ProductVectorBase


 template <class Scalar>
 RCP<VectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getNonconstVectorBlock(const int k)
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_IN_RANGE_UPPER_EXCLUSIVE( k, 0, numBlocks_ );
 #endif
   return multiVec_.getNonconstObj()->col(k);
 }


 template <class Scalar>
 RCP<const VectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getVectorBlock(const int k) const
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_IN_RANGE_UPPER_EXCLUSIVE( k, 0, numBlocks_ );
 #endif
   return multiVec_.getConstObj()->col(k);
 }


 // Overridden from ProductMultiVectorBase


 template <class Scalar>
 RCP<const ProductVectorSpaceBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::productSpace() const
 {
   return productSpace_;
 }


 template <class Scalar>
 bool DefaultMultiVectorProductVector<Scalar>::blockIsConst(const int k) const
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_IN_RANGE_UPPER_EXCLUSIVE( k, 0, numBlocks_ );
 #endif
   return multiVec_.isConst();
 }


 template <class Scalar>
 RCP<MultiVectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getNonconstMultiVectorBlock(const int k)
 {
   return getNonconstVectorBlock(k);
 }


 template <class Scalar>
 RCP<const MultiVectorBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getMultiVectorBlock(const int k) const
 {
   return getVectorBlock(k);
 }


 // Overridden public functions from VectorBase


 template <class Scalar>
 RCP< const VectorSpaceBase<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::space() const
 {
   return productSpace_;
 }


 // protected


 // Overridden protected functions from VectorBase


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::randomizeImpl(
   Scalar l,
   Scalar u
   )
 {
   for(int k = 0; k < numBlocks_; ++k) {
     multiVec_.getNonconstObj()->col(k)->randomize(l, u);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::absImpl(
   const VectorBase<Scalar>& x
   )
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT(productSpace_->isCompatible(*x.space()));
 #endif
   // Apply operation block-by-block if mv is also a ProductVector
   const RCP<const ProductVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductVectorBase<Scalar> >(Teuchos::rcpFromRef(x));
   if (nonnull(pv)) {
     for(int k = 0; k < numBlocks_; ++k) {
       multiVec_.getNonconstObj()->col(k)->abs(*pv->getVectorBlock(k));
     }
   } else {
     VectorDefaultBase<Scalar>::absImpl(x);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::reciprocalImpl(
   const VectorBase<Scalar>& x
   )
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT(productSpace_->isCompatible(*x.space()));
 #endif
   // Apply operation block-by-block if mv is also a ProductVector
   const RCP<const ProductVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductVectorBase<Scalar> >(Teuchos::rcpFromRef(x));
   if (nonnull(pv)) {
     for(int k = 0; k < numBlocks_; ++k) {
       multiVec_.getNonconstObj()->col(k)->reciprocal(*pv->getVectorBlock(k));
     }
   } else {
     VectorDefaultBase<Scalar>::reciprocalImpl(x);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::eleWiseScaleImpl(
   const VectorBase<Scalar>& x
   )
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT(productSpace_->isCompatible(*x.space()));
 #endif
   // Apply operation block-by-block if mv is also a ProductVector
   const RCP<const ProductVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductVectorBase<Scalar> >(Teuchos::rcpFromRef(x));
   if (nonnull(pv)) {
     for(int k = 0; k < numBlocks_; ++k) {
       multiVec_.getNonconstObj()->col(k)->ele_wise_scale(*pv->getVectorBlock(k));
     }
   } else {
     VectorDefaultBase<Scalar>::eleWiseScaleImpl(x);
   }
 }


 template <class Scalar>
 typename Teuchos::ScalarTraits<Scalar>::magnitudeType
 DefaultMultiVectorProductVector<Scalar>::norm2WeightedImpl(
   const VectorBase<Scalar>& x
   ) const
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT(productSpace_->isCompatible(*x.space()));
 #endif
   // Apply operation block-by-block if mv is also a ProductVector
   typedef ScalarTraits<Scalar> ST;
   const RCP<const ProductVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductVectorBase<Scalar> >(Teuchos::rcpFromRef(x));
   if (nonnull(pv)) {
     typename ST::magnitudeType norm = ST::magnitude(ST::zero());
     for(int k = 0; k < numBlocks_; ++k) {
       typename ST::magnitudeType subNorm
         = multiVec_.getConstObj()->col(k)->norm_2(*pv->getVectorBlock(k));
       norm += subNorm*subNorm;
     }
     return ST::magnitude(ST::squareroot(norm));
   } else {
     return VectorDefaultBase<Scalar>::norm2WeightedImpl(x);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::applyOpImpl(
   const RTOpPack::RTOpT<Scalar> &op,
   const ArrayView<const Ptr<const VectorBase<Scalar> > > &vecs,
   const ArrayView<const Ptr<VectorBase<Scalar> > > &targ_vecs,
   const Ptr<RTOpPack::ReductTarget> &reduct_obj,
   const Ordinal global_offset
   ) const
 {
   this->getDefaultProductVector()->applyOp(
     op, vecs, targ_vecs, reduct_obj, global_offset );
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::acquireDetachedVectorViewImpl(
   const Range1D& rng_in, RTOpPack::ConstSubVectorView<Scalar>* sub_vec
   ) const
 {
   this->getDefaultProductVector()->acquireDetachedView(rng_in,sub_vec);
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::releaseDetachedVectorViewImpl(
   RTOpPack::ConstSubVectorView<Scalar>* sub_vec
   ) const
 {
   this->getDefaultProductVector()->releaseDetachedView(sub_vec);
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::acquireNonconstDetachedVectorViewImpl(
   const Range1D& rng_in, RTOpPack::SubVectorView<Scalar>* sub_vec
   )
 {
   TEUCHOS_TEST_FOR_EXCEPT("ToDo: Implement DefaultMultiVectorProductVector<Scalar>::acquireNonconstDetachedVectorViewImpl(...)!");
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::commitNonconstDetachedVectorViewImpl(
   RTOpPack::SubVectorView<Scalar>* sub_vec
   )
 {
   TEUCHOS_TEST_FOR_EXCEPT("ToDo: Implement DefaultMultiVectorProductVector<Scalar>::commitNonconstDetachedVectorViewImpl(...)!");
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::setSubVectorImpl(
   const RTOpPack::SparseSubVectorT<Scalar>& sub_vec
   )
 {
   TEUCHOS_TEST_FOR_EXCEPT("ToDo: Implement DefaultMultiVectorProductVector<Scalar>::setSubVector(...)!");
 }


 // Overridden protected functions from VectorBase


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::assignImpl(Scalar alpha)
 {
   multiVec_.getNonconstObj()->assign(alpha);
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::assignMultiVecImpl(
   const MultiVectorBase<Scalar>& mv
   )
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_EQUALITY(mv.domain()->dim(), 1);
   TEUCHOS_ASSERT(productSpace_->isCompatible(*mv.range()));
 #endif
   const RCP<const ProductMultiVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductMultiVectorBase<Scalar> >(Teuchos::rcpFromRef(mv));
   if (nonnull(pv)) {
     for(int k = 0; k < numBlocks_; ++k) {
       multiVec_.getNonconstObj()->col(k)->assign(*pv->getMultiVectorBlock(k));
     }
   } else {
     MultiVectorDefaultBase<Scalar>::assignMultiVecImpl(mv);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::scaleImpl(Scalar alpha)
 {
   multiVec_.getNonconstObj()->scale(alpha);
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::updateImpl(
   Scalar alpha,
   const MultiVectorBase<Scalar>& mv
   )
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_EQUALITY(mv.domain()->dim(), 1);
   TEUCHOS_ASSERT(productSpace_->isCompatible(*mv.range()));
 #endif
   const RCP<const ProductMultiVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductMultiVectorBase<Scalar> >(Teuchos::rcpFromRef(mv));
   if (nonnull(pv)) {
     for(int k = 0; k < numBlocks_; ++k) {
       multiVec_.getNonconstObj()->col(k)->update(alpha, *pv->getMultiVectorBlock(k));
     }
   } else {
     MultiVectorDefaultBase<Scalar>::updateImpl(alpha, mv);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::linearCombinationImpl(
   const ArrayView<const Scalar>& alpha,
   const ArrayView<const Ptr<const MultiVectorBase<Scalar> > >& mv,
   const Scalar& beta
   )
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_EQUALITY(alpha.size(), mv.size());
   for (Ordinal i = 0; i < mv.size(); ++i) {
     TEUCHOS_ASSERT_EQUALITY(mv[i]->domain()->dim(), 1);
     TEUCHOS_ASSERT(productSpace_->isCompatible(*mv[i]->range()));
   }
 #endif

   // Apply operation block-by-block if each element of mv is also a ProductMultiVector
   bool allCastsSuccessful = true;
   Array<Ptr<const ProductMultiVectorBase<Scalar> > > pvs(mv.size());
   for (Ordinal i = 0; i < mv.size(); ++i) {
     pvs[i] = Teuchos::ptr_dynamic_cast<const ProductMultiVectorBase<Scalar> >(mv[i]);
     if (pvs[i].is_null()) {
       allCastsSuccessful = false;
       break;
     }
   }

   if (allCastsSuccessful) {
     Array<RCP<const MultiVectorBase<Scalar> > > blocks_rcp(pvs.size());
     Array<Ptr<const MultiVectorBase<Scalar> > > blocks(pvs.size());
     for (int k = 0; k < numBlocks_; ++k) {
       for (Ordinal i = 0; i < pvs.size(); ++i) {
         blocks_rcp[i] = pvs[i]->getMultiVectorBlock(k);
         blocks[i] = blocks_rcp[i].ptr();
       }
       multiVec_.getNonconstObj()->col(k)->linear_combination(alpha, blocks(), beta);
     }
   } else {
     MultiVectorDefaultBase<Scalar>::linearCombinationImpl(alpha, mv, beta);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::dotsImpl(
   const MultiVectorBase<Scalar>& mv,
   const ArrayView<Scalar>& prods
   ) const
 {
 #ifdef TEUCHOS_DEBUG
   TEUCHOS_ASSERT_EQUALITY(mv.domain()->dim(), 1);
   TEUCHOS_ASSERT_EQUALITY(prods.size(), 1);
   TEUCHOS_ASSERT(productSpace_->isCompatible(*mv.range()));
 #endif
   const RCP<const ProductMultiVectorBase<Scalar> > pv
     = Teuchos::rcp_dynamic_cast<const ProductMultiVectorBase<Scalar> >(Teuchos::rcpFromRef(mv));
   if (nonnull(pv)) {
     prods[0] = ScalarTraits<Scalar>::zero();
     for(int k = 0; k < numBlocks_; ++k) {
       Scalar prod;
       multiVec_.getConstObj()->col(k)->dots(*pv->getMultiVectorBlock(k), Teuchos::arrayView(&prod, 1));
       prods[0] += prod;
     }
   } else {
     MultiVectorDefaultBase<Scalar>::dotsImpl(mv, prods);
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::norms1Impl(
   const ArrayView<typename ScalarTraits<Scalar>::magnitudeType>& norms
   ) const
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT_EQUALITY(norms.size(), 1);
 #endif
   typedef ScalarTraits<Scalar> ST;
   norms[0] = ST::magnitude(ST::zero());
   for(int k = 0; k < numBlocks_; ++k) {
     norms[0] += multiVec_.getConstObj()->col(k)->norm_1();
   }
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::norms2Impl(
   const ArrayView<typename ScalarTraits<Scalar>::magnitudeType>& norms
   ) const
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT_EQUALITY(norms.size(), 1);
 #endif
   typedef ScalarTraits<Scalar> ST;
   norms[0] = ST::magnitude(ST::zero());
   for(int k = 0; k < numBlocks_; ++k) {
     typename ST::magnitudeType subNorm = multiVec_.getConstObj()->col(k)->norm_2();
     norms[0] += subNorm*subNorm;
   }
   norms[0] = ST::magnitude(ST::squareroot(norms[0]));
 }


 template <class Scalar>
 void DefaultMultiVectorProductVector<Scalar>::normsInfImpl(
   const ArrayView<typename ScalarTraits<Scalar>::magnitudeType>& norms
   ) const
 {
 #ifdef TEUCHOS_DEBUG
     TEUCHOS_ASSERT_EQUALITY(norms.size(), 1);
 #endif
   typedef ScalarTraits<Scalar> ST;
   norms[0] = ST::magnitude(ST::zero());
   for(int k = 0; k < numBlocks_; ++k) {
     typename ST::magnitudeType subNorm = multiVec_.getConstObj()->col(k)->norm_inf();
     if (subNorm > norms[0])
       norms[0] = subNorm;
   }
 }


 // private


 template <class Scalar>
 RCP<const DefaultProductVector<Scalar> >
 DefaultMultiVectorProductVector<Scalar>::getDefaultProductVector() const
 {

   // This function exists since in general we can not create views of a column
   // vectors and expect the changes to be mirrored in the mulit-vector
   // automatically.  Later, we might be able to change this once we have a
   // Thyra::MultiVectorBase::hasDirectColumnVectorView() function and it
   // returns true.  Until then, this is the safe way to do this ...

   Array<RCP<const VectorBase<Scalar> > > vecArray;
   for ( int k = 0; k < numBlocks_; ++k) {
     vecArray.push_back(multiVec_.getConstObj()->col(k));
   }

   return Thyra::defaultProductVector<Scalar>(
     productSpace_->getDefaultProductVectorSpace(),
     vecArray()
     );

 }


 } // namespace Thyra


 #endif // THYRA_DEFAULT_MULTI_VECTOR_PRODUCT_VECTOR_HPP
Thyra::VectorBase::space
virtual RCP< const VectorSpaceBase< Scalar > > space() const =0
Return a smart pointer to the vector space that this vector belongs to.

Thyra::ProductMultiVectorBase
Base interface for product multi-vectors.
Definition: Thyra_ProductMultiVectorBase.hpp:66

Thyra::DefaultMultiVectorProductVector::releaseDetachedVectorViewImpl
void releaseDetachedVectorViewImpl(RTOpPack::ConstSubVectorView< Scalar > *sub_vec) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:394

THYRA_ASSERT_VEC_SPACES
#define THYRA_ASSERT_VEC_SPACES(FUNC_NAME, VS1, VS2)
This is a very useful macro that should be used to validate that two vector spaces are compatible...
Definition: Thyra_AssertOp.hpp:188

Thyra::DefaultMultiVectorProductVector::normsInfImpl
virtual void normsInfImpl(const ArrayView< typename ScalarTraits< Scalar >::magnitudeType > &norms) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:592

Thyra::LinearOpBase::range
virtual RCP< const VectorSpaceBase< Scalar > > range() const =0
Return a smart pointer for the range space for this operator.

Thyra::ProductVectorBase
Base interface for product vectors.
Definition: Thyra_ProductVectorBase.hpp:87

Thyra::DefaultMultiVectorProductVector::assignImpl
virtual void assignImpl(Scalar alpha)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:433

Thyra::DefaultMultiVectorProductVector::eleWiseScaleImpl
virtual void eleWiseScaleImpl(const VectorBase< Scalar > &x)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:323

Thyra::MultiVectorDefaultBase::assignMultiVecImpl
virtual void assignMultiVecImpl(const MultiVectorBase< Scalar > &mv)
Default implementation of assign(MV) using RTOps.
Definition: Thyra_MultiVectorDefaultBase_def.hpp:104

Thyra::DefaultMultiVectorProductVector::blockIsConst
bool blockIsConst(const int k) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:226

Thyra::DefaultMultiVectorProductVector::dotsImpl
virtual void dotsImpl(const MultiVectorBase< Scalar > &mv, const ArrayView< Scalar > &prods) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:532

Thyra::VectorDefaultBase::eleWiseScaleImpl
virtual void eleWiseScaleImpl(const VectorBase< Scalar > &x)
Default implementation of ele_wise_scale using RTOps.
Definition: Thyra_VectorDefaultBase_def.hpp:241

Thyra::VectorDefaultBase::reciprocalImpl
virtual void reciprocalImpl(const VectorBase< Scalar > &x)
Default implementation of reciprocal using RTOps.
Definition: Thyra_VectorDefaultBase_def.hpp:231

Thyra::MultiVectorDefaultBase::linearCombinationImpl
virtual void linearCombinationImpl(const ArrayView< const Scalar > &alpha, const ArrayView< const Ptr< const MultiVectorBase< Scalar > > > &mv, const Scalar &beta)
Default implementation of linear_combination using RTOps.
Definition: Thyra_MultiVectorDefaultBase_def.hpp:147

Thyra::DefaultMultiVectorProductVector::acquireDetachedVectorViewImpl
void acquireDetachedVectorViewImpl(const Range1D &rng, RTOpPack::ConstSubVectorView< Scalar > *sub_vec) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:385

Thyra::VectorDefaultBase::absImpl
virtual void absImpl(const VectorBase< Scalar > &x)
Default implementation of abs using RTOps.
Definition: Thyra_VectorDefaultBase_def.hpp:221

Thyra::DefaultMultiVectorProductVector
Concrete implementation of a product vector which is really composed out of the columns of a multi-ve...
Definition: Thyra_DefaultMultiVectorProductVector_decl.hpp:70

Thyra::DefaultMultiVectorProductVector::space
RCP< const VectorSpaceBase< Scalar > > space() const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:256

Thyra::ProductMultiVectorBase::getMultiVectorBlock
virtual Teuchos::RCP< const MultiVectorBase< Scalar > > getMultiVectorBlock(const int k) const =0
Returns a non-persisting const view of the (zero-based) kth block multi-vector.

Thyra::DefaultMultiVectorProductVector::scaleImpl
virtual void scaleImpl(Scalar alpha)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:461

Thyra::DefaultMultiVectorProductVector::commitNonconstDetachedVectorViewImpl
void commitNonconstDetachedVectorViewImpl(RTOpPack::SubVectorView< Scalar > *sub_vec)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:412

Thyra::DefaultMultiVectorProductVector::uninitialize
void uninitialize()
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:132

Thyra::DefaultMultiVectorProductVector::getMultiVector
RCP< const MultiVectorBase< Scalar > > getMultiVector() const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:125

Thyra::Ordinal
Teuchos::Ordinal Ordinal
Type for the dimension of a vector space. `*.
Definition: Thyra_OperatorVectorTypes.hpp:127

Thyra::MultiVectorBase
Interface for a collection of column vectors called a multi-vector.
Definition: Thyra_MultiVectorBase_decl.hpp:493

Thyra::MultiVectorBase::col
RCP< const VectorBase< Scalar > > col(Ordinal j) const
Calls colImpl().
Definition: Thyra_MultiVectorBase_decl.hpp:641

Thyra::MultiVectorDefaultBase::dotsImpl
virtual void dotsImpl(const MultiVectorBase< Scalar > &mv, const ArrayView< Scalar > &prods) const
Default implementation of dots using RTOps.
Definition: Thyra_MultiVectorDefaultBase_def.hpp:221

Thyra::DefaultMultiVectorProductVector::norm2WeightedImpl
virtual Teuchos::ScalarTraits< Scalar >::magnitudeType norm2WeightedImpl(const VectorBase< Scalar > &x) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:345

Thyra::DefaultMultiVectorProductVector::acquireNonconstDetachedVectorViewImpl
void acquireNonconstDetachedVectorViewImpl(const Range1D &rng, RTOpPack::SubVectorView< Scalar > *sub_vec)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:403

Thyra::DefaultMultiVectorProductVector::absImpl
virtual void absImpl(const VectorBase< Scalar > &x)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:281

Thyra::VectorBase
Abstract interface for finite-dimensional dense vectors.
Definition: Thyra_OperatorVectorTypes.hpp:370

Thyra::DefaultMultiVectorProductVector::describe
void describe(Teuchos::FancyOStream &out, const Teuchos::EVerbosityLevel verbLevel) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:157

Thyra::DefaultMultiVectorProductVectorSpace
Standard concrete implementation of a product vector space that creates product vectors fromed implic...
Definition: Thyra_DefaultMultiVectorProductVector_decl.hpp:55

Thyra::DefaultMultiVectorProductVector::norms2Impl
virtual void norms2Impl(const ArrayView< typename ScalarTraits< Scalar >::magnitudeType > &norms) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:574

Thyra::DefaultMultiVectorProductVector::initialize
void initialize(const RCP< const DefaultMultiVectorProductVectorSpace< Scalar > > &productSpace, const RCP< MultiVectorBase< Scalar > > &multiVec)
Initialize with a non-const multi-vector.
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:66

Thyra::DefaultMultiVectorProductVector::applyOpImpl
void applyOpImpl(const RTOpPack::RTOpT< Scalar > &op, const ArrayView< const Ptr< const VectorBase< Scalar > > > &vecs, const ArrayView< const Ptr< VectorBase< Scalar > > > &targ_vecs, const Ptr< RTOpPack::ReductTarget > &reduct_obj, const Ordinal global_offset) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:371

Thyra::DefaultMultiVectorProductVector::updateImpl
virtual void updateImpl(Scalar alpha, const MultiVectorBase< Scalar > &mv)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:468

Thyra::LinearOpBase::domain
virtual RCP< const VectorSpaceBase< Scalar > > domain() const =0
Return a smart pointer for the domain space for this operator.

Thyra::DefaultMultiVectorProductVector::DefaultMultiVectorProductVector
DefaultMultiVectorProductVector()
Construct to uninitialized.
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:59

Thyra::DefaultMultiVectorProductVector::description
std::string description() const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:144

Thyra::DefaultMultiVectorProductVector::getNonconstMultiVector
RCP< MultiVectorBase< Scalar > > getNonconstMultiVector()
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:117

Thyra::DefaultMultiVectorProductVector::assignMultiVecImpl
virtual void assignMultiVecImpl(const MultiVectorBase< Scalar > &mv)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:440

Thyra::DefaultMultiVectorProductVector::productSpace
RCP< const ProductVectorSpaceBase< Scalar > > productSpace() const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:219

Thyra::DefaultMultiVectorProductVector::randomizeImpl
virtual void randomizeImpl(Scalar l, Scalar u)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:269

Thyra::DefaultMultiVectorProductVector::getNonconstMultiVectorBlock
RCP< MultiVectorBase< Scalar > > getNonconstMultiVectorBlock(const int k)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:237

Thyra::DefaultMultiVectorProductVector::norms1Impl
virtual void norms1Impl(const ArrayView< typename ScalarTraits< Scalar >::magnitudeType > &norms) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:558

Thyra::DefaultMultiVectorProductVector::getMultiVectorBlock
RCP< const MultiVectorBase< Scalar > > getMultiVectorBlock(const int k) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:245

Thyra::DefaultMultiVectorProductVector::getNonconstVectorBlock
RCP< VectorBase< Scalar > > getNonconstVectorBlock(const int k)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:194

Thyra
Definition: Thyra_LinearOpBase_decl.hpp:51

Thyra::DefaultMultiVectorProductVector::linearCombinationImpl
virtual void linearCombinationImpl(const ArrayView< const Scalar > &alpha, const ArrayView< const Ptr< const MultiVectorBase< Scalar > > > &mv, const Scalar &beta)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:490

Thyra::DefaultMultiVectorProductVector::getVectorBlock
RCP< const VectorBase< Scalar > > getVectorBlock(const int k) const
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:205

Thyra::VectorDefaultBase::norm2WeightedImpl
virtual Teuchos::ScalarTraits< Scalar >::magnitudeType norm2WeightedImpl(const VectorBase< Scalar > &x) const
Default implementation of norm_2 (weighted) using RTOps.
Definition: Thyra_VectorDefaultBase_def.hpp:304

Thyra::MultiVectorDefaultBase::updateImpl
virtual void updateImpl(Scalar alpha, const MultiVectorBase< Scalar > &mv)
Default implementation of update using RTOps.
Definition: Thyra_MultiVectorDefaultBase_def.hpp:134

Thyra::DefaultMultiVectorProductVector::reciprocalImpl
virtual void reciprocalImpl(const VectorBase< Scalar > &x)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:302

Thyra::Range1D
Teuchos::Range1D Range1D
Definition: Thyra_OperatorVectorTypes.hpp:97

Thyra::DefaultMultiVectorProductVector::setSubVectorImpl
void setSubVectorImpl(const RTOpPack::SparseSubVectorT< Scalar > &sub_vec)
Definition: Thyra_DefaultMultiVectorProductVector_def.hpp:421