Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > Class Template Reference

A distributed dense vector. More...

#include <Tpetra_Vector_decl.hpp>

Inheritance diagram for Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >:

Public Types
Typedefs to facilitate template metaprogramming
typedef Scalar	scalar_type
	This class' first template parameter; the type of each entry in the Vector. More...
typedef base_type::impl_scalar_type	impl_scalar_type
	The type used internally in place of Scalar. More...
typedef LocalOrdinal	local_ordinal_type
	This class' second template parameter; the type of local indices. More...
typedef GlobalOrdinal	global_ordinal_type
	This class' third template parameter; the type of global indices. More...
typedef Node::device_type	device_type
	The Kokkos device type. More...
typedef Node	node_type
	The Kokkos Node type. More...
typedef base_type::dot_type	dot_type
	Type of an inner ("dot") product result. More...
typedef base_type::mag_type	mag_type
	Type of a norm result. More...
typedef base_type::dual_view_type	dual_view_type
	Kokkos::DualView specialization used by this class. More...
typedef base_type::wrapped_dual_view_type	wrapped_dual_view_type
	WrappedDualView specialization used by this class. More...
typedef base_type::map_type	map_type
	The type of the Map specialization used by this class. More...
Typedefs to facilitate template metaprogramming.
using	execution_space = typename device_type::execution_space
	Type of the (new) Kokkos execution space. More...
using	host_view_type = typename dual_view_type::t_host
using	device_view_type = typename dual_view_type::t_dev
Typedefs
using	packet_type = typename::Kokkos::ArithTraits< Scalar >::val_type
	The type of each datum being sent or received in an Import or Export. More...

Public Member Functions
virtual void	removeEmptyProcessesInPlace (const Teuchos::RCP< const map_type > &newMap) override
	Remove processes owning zero rows from the Map and their communicator. More...
void	setCopyOrView (const Teuchos::DataAccess copyOrView)
	Set whether this has copy (copyOrView = Teuchos::Copy) or view (copyOrView = Teuchos::View) semantics. More...
Teuchos::DataAccess	getCopyOrView () const
	Get whether this has copy (copyOrView = Teuchos::Copy) or view (copyOrView = Teuchos::View) semantics. More...
void	assign (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &src)
	Copy the contents of src into *this (deep copy). More...
Teuchos::RCP< MultiVector< T, LocalOrdinal, GlobalOrdinal, Node > >	convert () const
	Return another MultiVector with the same entries, but converted to a different Scalar type T. More...
bool	isSameSize (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &vec) const
Constructors and destructor
	Vector ()
	Default constructor: makes a Vector with no rows or columns. More...
	Vector (const Teuchos::RCP< const map_type > &map, const bool zeroOut=true)
	Basic constructor. More...
	Vector (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &source, const Teuchos::DataAccess copyOrView)
	Copy constructor (shallow or deep copy). More...
	Vector (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &source, const Teuchos::RCP< const map_type > &map, const local_ordinal_type rowOffset=0)
	"Offset view" constructor that views the input Vector's local data, but with the given Map, using the given row offset. More...
	Vector (const Teuchos::RCP< const map_type > &map, const Teuchos::ArrayView< const Scalar > &A)
	Set vector values from an existing array (copy) More...
	Vector (const Teuchos::RCP< const map_type > &map, const dual_view_type &view)
	Expert mode constructor, that takes a Kokkos::DualView of the Vector's data, and returns a Vector that views those data. More...
	Vector (const Teuchos::RCP< const map_type > &map, const dual_view_type &view, const dual_view_type &origView)
	Expert mode constructor, that takes a Kokkos::DualView of the Vector's data and the "original" Kokkos::DualView of the data, and returns a Vector that views those data. More...
	Vector (const Teuchos::RCP< const map_type > &map, const wrapped_dual_view_type &d_view)
	Expert mode constructor, that takes a WrappedDualView of the MultiVector's data. More...
	Vector (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &X, const size_t j)
	Create a Vector that views a single column of the input MultiVector. More...
	Vector (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &)=default
	Copy constructor (shallow copy). More...
	Vector (Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &&)=default
	Move constructor (shallow move). More...
Vector &	operator= (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &)=default
	Copy assignment (shallow copy). More...
Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &	operator= (Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &&)=default
	Move assigment (shallow move). More...
virtual	~Vector ()=default
	Destructor (virtual for memory safety of derived classes). More...
Post-construction modification routines
void	replaceGlobalValue (const GlobalOrdinal globalRow, const Scalar &value)
	Replace current value at the specified location with specified value. More...
void	sumIntoGlobalValue (const GlobalOrdinal globalRow, const Scalar &value, const bool atomic=base_type::useAtomicUpdatesByDefault)
	Add value to existing value, using global (row) index. More...
void	replaceLocalValue (const LocalOrdinal myRow, const Scalar &value)
	Replace current value at the specified location with specified values. More...
void	sumIntoLocalValue (const LocalOrdinal myRow, const Scalar &value, const bool atomic=base_type::useAtomicUpdatesByDefault)
	Add value to existing value, using local (row) index. More...
Extraction methods
void	get1dCopy (const Teuchos::ArrayView< Scalar > &A) const
	Return multi-vector values in user-provided two-dimensional array (using Teuchos memory management classes). More...
Teuchos::ArrayRCP< Scalar >	getDataNonConst ()
	View of the local values of this vector. More...
Teuchos::ArrayRCP< const Scalar >	getData () const
	Const view of the local values of this vector. More...
Teuchos::RCP< const Vector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	offsetView (const Teuchos::RCP< const map_type > &subMap, const size_t offset) const
Teuchos::RCP< Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > >	offsetViewNonConst (const Teuchos::RCP< const map_type > &subMap, const size_t offset)
Mathematical methods
dot_type	dot (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &y) const
	Return the dot product of this Vector and the input Vector x. More...
mag_type	norm1 () const
	Return the one-norm of this Vector. More...
mag_type	norm2 () const
	Return the two-norm of this Vector. More...
mag_type	normInf () const
	Return the infinity-norm of this Vector. More...
Scalar	meanValue () const
	Compute mean (average) value of this Vector. More...
Implementation of the Teuchos::Describable interface
virtual std::string	description () const
	Return a one-line description of this object. More...
virtual void	describe (Teuchos::FancyOStream &out, const Teuchos::EVerbosityLevel verbLevel=Teuchos::Describable::verbLevel_default) const
	Describe this object in a human-readable way to the given output stream. More...
Constructors and destructor
void	swap (MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &mv)
	Swap contents of mv with contents of *this. More...
Get a copy or view of a subset of rows and/or columns
The following methods get either a (deep) copy or a view (shallow copy) of a subset of rows and/or columns of the MultiVector. They return one of the following: Another MultiVector A Kokkos::View or Kokkos::DualView A Teuchos::ArrayRCP (see the Teuchos Memory Management Classes) We prefer use of Kokkos classes to Teuchos Memory Management Classes. In particular, Teuchos::ArrayRCP reference counts are not thread safe, while Kokkos::View (and Kokkos::DualView) reference counts are thread safe. Not all of these methods are valid for a particular MultiVector. For instance, calling a method that accesses a view of the data in a 1-D format (i.e., get1dView) requires that the target MultiVector have constant stride. This category of methods also includes sync(), modify(), and getLocalView(), which help MultiVector implement DualView semantics.
Teuchos::RCP< MultiVector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subCopy (const Teuchos::Range1D &colRng) const
	Return a MultiVector with copies of selected columns. More...
Teuchos::RCP< MultiVector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subCopy (const Teuchos::ArrayView< const size_t > &cols) const
	Return a MultiVector with copies of selected columns. More...
Teuchos::RCP< const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subView (const Teuchos::Range1D &colRng) const
	Return a const MultiVector with const views of selected columns. More...
Teuchos::RCP< const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subView (const Teuchos::ArrayView< const size_t > &cols) const
	Return a const MultiVector with const views of selected columns. More...
Teuchos::RCP< MultiVector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subViewNonConst (const Teuchos::Range1D &colRng)
	Return a MultiVector with views of selected columns. More...
Teuchos::RCP< MultiVector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	subViewNonConst (const Teuchos::ArrayView< const size_t > &cols)
	Return a MultiVector with views of selected columns. More...
Teuchos::RCP< const Vector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	getVector (const size_t j) const
	Return a Vector which is a const view of column j. More...
Teuchos::RCP< Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > >	getVectorNonConst (const size_t j)
	Return a Vector which is a nonconst view of column j. More...
Teuchos::ArrayRCP< const Scalar >	getData (size_t j) const
	Const view of the local values in a particular vector of this multivector. More...
Teuchos::ArrayRCP< Scalar >	getDataNonConst (size_t j)
	View of the local values in a particular vector of this multivector. More...
void	get1dCopy (const Teuchos::ArrayView< Scalar > &A, const size_t LDA) const
	Fill the given array with a copy of this multivector's local values. More...
void	get2dCopy (const Teuchos::ArrayView< const Teuchos::ArrayView< Scalar > > &ArrayOfPtrs) const
	Fill the given array with a copy of this multivector's local values. More...
Teuchos::ArrayRCP< const Scalar >	get1dView () const
	Const persisting (1-D) view of this multivector's local values. More...
Teuchos::ArrayRCP < Teuchos::ArrayRCP< const Scalar > >	get2dView () const
	Return const persisting pointers to values. More...
Teuchos::ArrayRCP< Scalar >	get1dViewNonConst ()
	Nonconst persisting (1-D) view of this multivector's local values. More...
Teuchos::ArrayRCP < Teuchos::ArrayRCP< Scalar > >	get2dViewNonConst ()
	Return non-const persisting pointers to values. More...
dual_view_type::t_host::const_type	getLocalViewHost (Access::ReadOnlyStruct) const
	Return a read-only, up-to-date view of this MultiVector's local data on host. This requires that there are no live device-space views. More...
dual_view_type::t_host	getLocalViewHost (Access::ReadWriteStruct)
	Return a mutable, up-to-date view of this MultiVector's local data on host. This requires that there are no live device-space views. More...
dual_view_type::t_host	getLocalViewHost (Access::OverwriteAllStruct)
	Return a mutable view of this MultiVector's local data on host, assuming all existing data will be overwritten. This requires that there are no live device-space views. More...
dual_view_type::t_dev::const_type	getLocalViewDevice (Access::ReadOnlyStruct) const
	Return a read-only, up-to-date view of this MultiVector's local data on device. This requires that there are no live host-space views. More...
dual_view_type::t_dev	getLocalViewDevice (Access::ReadWriteStruct)
	Return a mutable, up-to-date view of this MultiVector's local data on device. This requires that there are no live host-space views. More...
dual_view_type::t_dev	getLocalViewDevice (Access::OverwriteAllStruct)
	Return a mutable view of this MultiVector's local data on device, assuming all existing data will be overwritten. This requires that there are no live host-space views. More...
wrapped_dual_view_type	getWrappedDualView () const
	Return the wrapped dual view holding this MultiVector's local data. More...
bool	need_sync () const
	Whether this MultiVector needs synchronization to the given space. More...
bool	need_sync_host () const
	Whether this MultiVector needs synchronization to the host. More...
bool	need_sync_device () const
	Whether this MultiVector needs synchronization to the device. More...
std::remove_reference < decltype(std::declval < dual_view_type >).template view< TargetDeviceType > ))>::type::const_type	getLocalView (Access::ReadOnlyStruct s) const
	Return a view of the local data on a specific device, with the given access mode. The return type is either dual_view_type::t_dev, dual_view_type::t_host, or the const_type of one of those. More...
std::remove_reference < decltype(std::declval < dual_view_type >).template view< TargetDeviceType > ))>::type	getLocalView (Access::ReadWriteStruct s)
std::remove_reference < decltype(std::declval < dual_view_type >).template view< TargetDeviceType > ))>::type	getLocalView (Access::OverwriteAllStruct s)
Mathematical methods
void	dot (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Teuchos::ArrayView< dot_type > &dots) const
	Compute the dot product of each corresponding pair of vectors (columns) in A and B. More...
std::enable_if< !(std::is_same < dot_type, T >::value), void > ::type	dot (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Teuchos::ArrayView< T > &dots) const
	Compute the dot product of each corresponding pair of vectors (columns) in A and B. More...
std::enable_if< !(std::is_same < dot_type, T >::value), void > ::type	dot (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, std::vector< T > &dots) const
	Like the above dot() overload, but for std::vector output. More...
void	dot (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Kokkos::View< dot_type *, Kokkos::HostSpace > &norms) const
	Compute the dot product of each corresponding pair of vectors (columns) in A and B, storing the result in a device View. More...
void	dot (typename std::enable_if< std::is_same< typename ViewType::value_type, dot_type >::value &&std::is_same< typename ViewType::memory_space, typename device_type::memory_space >::value, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node >>::type &A, const ViewType &dots) const
std::enable_if< !(std::is_same < dot_type, T >::value), void > ::type	dot (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Kokkos::View< T *, device_type > &dots) const
	Compute the dot product of each corresponding pair of vectors (columns) in A and B, storing the result in a device view. More...
void	abs (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A)
	Put element-wise absolute values of input Multi-vector in target: A = abs(this) More...
void	reciprocal (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A)
	Put element-wise reciprocal values of input Multi-vector in target, this(i,j) = 1/A(i,j). More...
void	scale (const Scalar &alpha)
	Scale in place: this = alpha*this. More...
void	scale (const Teuchos::ArrayView< const Scalar > &alpha)
	Scale each column in place: this[j] = alpha[j]*this[j]. More...
void	scale (const Kokkos::View< const impl_scalar_type *, device_type > &alpha)
	Scale each column in place: this[j] = alpha[j]*this[j]. More...
void	scale (const Scalar &alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A)
	Scale in place: this = alpha * A. More...
void	update (const Scalar &alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Scalar &beta)
	Update: this = beta*this + alpha*A. More...
void	update (const Scalar &alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const Scalar &beta, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &B, const Scalar &gamma)
	Update: this = gamma*this + alpha*A + beta*B. More...
void	norm1 (const Kokkos::View< mag_type *, Kokkos::HostSpace > &norms) const
	Compute the one-norm of each vector (column), storing the result in a host view. More...
std::enable_if< std::is_same < typename ViewType::value_type, mag_type > ::value &&std::is_same < typename ViewType::memory_space, typename device_type::memory_space > ::value >::type	norm1 (const ViewType &norms) const
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	norm1 (const Kokkos::View< T *, device_type > &norms) const
	Compute the one-norm of each vector (column), storing the result in a device view. More...
void	norm1 (const Teuchos::ArrayView< mag_type > &norms) const
	Compute the one-norm of each vector (column). More...
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	norm1 (const Teuchos::ArrayView< T > &norms) const
	Compute the one-norm of each vector (column). More...
void	norm2 (const Kokkos::View< mag_type *, Kokkos::HostSpace > &norms) const
	Compute the two-norm of each vector (column), storing the result in a host View. More...
std::enable_if< std::is_same < typename ViewType::value_type, mag_type > ::value &&std::is_same < typename ViewType::memory_space, typename device_type::memory_space > ::value >::type	norm2 (const ViewType &norms) const
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	norm2 (const Kokkos::View< T *, device_type > &norms) const
	Compute the two-norm of each vector (column), storing the result in a device view. More...
void	norm2 (const Teuchos::ArrayView< mag_type > &norms) const
	Compute the two-norm of each vector (column). More...
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	norm2 (const Teuchos::ArrayView< T > &norms) const
	Compute the two-norm of each vector (column). More...
void	normInf (const Kokkos::View< mag_type *, Kokkos::HostSpace > &norms) const
	Compute the infinity-norm of each vector (column), storing the result in a host View. More...
std::enable_if< std::is_same < typename ViewType::value_type, mag_type > ::value &&std::is_same < typename ViewType::memory_space, typename device_type::memory_space > ::value >::type	normInf (const ViewType &norms) const
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	normInf (const Kokkos::View< T *, device_type > &norms) const
	Compute the infinity-norm of each vector (column), storing the result in a device view. More...
void	normInf (const Teuchos::ArrayView< mag_type > &norms) const
	Compute the infinity-norm of each vector (column), storing the result in a Teuchos::ArrayView. More...
std::enable_if< !(std::is_same < mag_type, T >::value), void > ::type	normInf (const Teuchos::ArrayView< T > &norms) const
	Compute the infinity-norm of each vector (column), storing the result in a Teuchos::ArrayView. More...
void	meanValue (const Teuchos::ArrayView< impl_scalar_type > &means) const
	Compute mean (average) value of each column. More...
std::enable_if<!std::is_same < impl_scalar_type, T >::value, void >::type	meanValue (const Teuchos::ArrayView< T > &means) const
void	multiply (Teuchos::ETransp transA, Teuchos::ETransp transB, const Scalar &alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &B, const Scalar &beta)
	Matrix-matrix multiplication: this = beta*this + alpha*op(A)*op(B). More...
void	elementWiseMultiply (Scalar scalarAB, const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &A, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &B, Scalar scalarThis)
	Multiply a Vector A elementwise by a MultiVector B. More...
Attribute access functions
size_t	getNumVectors () const
	Number of columns in the multivector. More...
size_t	getLocalLength () const
	Local number of rows on the calling process. More...
global_size_t	getGlobalLength () const
	Global number of rows in the multivector. More...
size_t	getStride () const
	Stride between columns in the multivector. More...
bool	isConstantStride () const
	Whether this multivector has constant stride between columns. More...
bool	aliases (const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &other) const
	Whether this multivector's memory might alias other. This is conservative: if either this or other is not constant stride, then it simply checks whether the contiguous memory allocations overlap. It doesn't check whether the sets of columns overlap. This is a symmetric relation: X.aliases(Y) == Y.aliases(X). More...
Methods for use only by experts
virtual void	removeEmptyProcessesInPlace (const Teuchos::RCP< const map_type > &newMap)
	Remove processes which contain no entries in this object's Map. More...
Public methods for redistributing data
void	doImport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
	Import data into this object using an Import object ("forward mode"). More...
void	doImport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
	Import data into this object using an Export object ("reverse mode"). More...
void	doExport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
	Export data into this object using an Export object ("forward mode"). More...
void	doExport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
	Export data into this object using an Import object ("reverse mode"). More...
void	beginImport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
void	beginImport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
void	beginExport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
void	beginExport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
void	endImport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
void	endImport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
void	endExport (const SrcDistObject &source, const Export< LocalOrdinal, GlobalOrdinal, Node > &exporter, const CombineMode CM, const bool restrictedMode=false)
void	endExport (const SrcDistObject &source, const Import< LocalOrdinal, GlobalOrdinal, Node > &importer, const CombineMode CM, const bool restrictedMode=false)
bool	transferArrived () const
	Whether the data from an import/export operation has arrived, and is ready for the unpack and combine step. More...
Attribute accessor methods
bool	isDistributed () const
	Whether this is a globally distributed object. More...
virtual Teuchos::RCP< const map_type >	getMap () const
	The Map describing the parallel distribution of this object. More...
I/O methods
void	print (std::ostream &os) const
	Print this object to the given output stream. More...

Protected Member Functions
virtual void	doTransfer (const SrcDistObject &src, const ::Tpetra::Details::Transfer< local_ordinal_type, global_ordinal_type, node_type > &transfer, const char modeString[], const ReverseOption revOp, const CombineMode CM, const bool restrictedMode)
	Redistribute data across (MPI) processes. More...
virtual bool	reallocArraysForNumPacketsPerLid (const size_t numExportLIDs, const size_t numImportLIDs)
	Reallocate numExportPacketsPerLID_ and/or numImportPacketsPerLID_, if necessary. More...
void	beginTransfer (const SrcDistObject &src, const ::Tpetra::Details::Transfer< local_ordinal_type, global_ordinal_type, node_type > &transfer, const char modeString[], const ReverseOption revOp, const CombineMode CM, const bool restrictedMode)
	Implementation detail of doTransfer. More...
Misc. implementation details
std::string	descriptionImpl (const std::string &className) const
	Implementation of description() for this class, and its subclass Vector. More...
std::string	localDescribeToString (const Teuchos::EVerbosityLevel vl) const
	Print the calling process' verbose describe() information to the returned string. More...
void	describeImpl (Teuchos::FancyOStream &out, const std::string &className, const Teuchos::EVerbosityLevel verbLevel=Teuchos::Describable::verbLevel_default) const
	Implementation of describe() for this class, and its subclass Vector. More...
bool	vectorIndexOutOfRange (const size_t VectorIndex) const
Teuchos::ArrayRCP< T >	getSubArrayRCP (Teuchos::ArrayRCP< T > arr, size_t j) const
	Persisting view of j-th column in the given ArrayRCP. More...
size_t	getOrigNumLocalRows () const
	"Original" number of rows in the (local) data. More...
size_t	getOrigNumLocalCols () const
	"Original" number of columns in the (local) data. More...

Protected Attributes
wrapped_dual_view_type	view_
	The Kokkos::DualView containing the MultiVector's data. More...
Teuchos::Array< size_t >	whichVectors_
	Indices of columns this multivector is viewing. More...

Related Functions
(Note that these are not member functions.)
template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >
Teuchos::RCP< MultiVector < Scalar, LocalOrdinal, GlobalOrdinal, Node > >	createMultiVector (const Teuchos::RCP< const Map< LocalOrdinal, GlobalOrdinal, Node > > &map, const size_t numVectors)
	Nonmember MultiVector "constructor": Create a MultiVector from a given Map. More...
template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >
Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >	createCopy (const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &src)
	Return a deep copy of the given Vector. More...
template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >
Teuchos::RCP< Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > >	createVector (const Teuchos::RCP< const Map< LocalOrdinal, GlobalOrdinal, Node > > &map)
	Nonmember Vector "constructor": Create a Vector from a given Map. More...

Methods implemented by subclasses and used by doTransfer().
The doTransfer() method uses the subclass' implementations of these methods to implement data transfer. Subclasses of DistObject must implement these methods. This is an instance of the Template Method Pattern. ("Template" here doesn't mean "C++ template"; it means "pattern with holes that are filled in by the subclass' method implementations.")
Teuchos::RCP< const map_type >	map_
	The Map over which this object is distributed. More...
Kokkos::DualView< packet_type *, buffer_device_type >	imports_
	Buffer into which packed data are imported (received from other processes). More...
Kokkos::DualView< size_t *, buffer_device_type >	numImportPacketsPerLID_
	Number of packets to receive for each receive operation. More...
Kokkos::DualView< packet_type *, buffer_device_type >	exports_
	Buffer from which packed data are exported (sent to other processes). More...
Kokkos::DualView< size_t *, buffer_device_type >	numExportPacketsPerLID_
	Number of packets to send for each send operation. More...
virtual void	copyAndPermute (const SrcDistObject &source, const size_t numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteFromLIDs, const CombineMode CM)
	Perform copies and permutations that are local to the calling (MPI) process. More...
virtual void	copyAndPermute (const SrcDistObject &source, const size_t numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteFromLIDs, const CombineMode CM, const execution_space &space)
	Same as copyAndPermute, but do operations in space. More...
virtual void	packAndPrepare (const SrcDistObject &source, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &exportLIDs, Kokkos::DualView< packet_type *, buffer_device_type > &exports, Kokkos::DualView< size_t *, buffer_device_type > numPacketsPerLID, size_t &constantNumPackets)
	Pack data and metadata for communication (sends). More...
virtual void	packAndPrepare (const SrcDistObject &source, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &exportLIDs, Kokkos::DualView< packet_type *, buffer_device_type > &exports, Kokkos::DualView< size_t *, buffer_device_type > numPacketsPerLID, size_t &constantNumPackets, const execution_space &space)
	Same as packAndPrepare, but in an execution space instance. More...
virtual void	unpackAndCombine (const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &importLIDs, Kokkos::DualView< packet_type *, buffer_device_type > imports, Kokkos::DualView< size_t *, buffer_device_type > numPacketsPerLID, const size_t constantNumPackets, const CombineMode combineMode)
	Perform any unpacking and combining after communication. More...
virtual void	unpackAndCombine (const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &importLIDs, Kokkos::DualView< packet_type *, buffer_device_type > imports, Kokkos::DualView< size_t *, buffer_device_type > numPacketsPerLID, const size_t constantNumPackets, const CombineMode combineMode, const execution_space &space)
std::unique_ptr< std::string >	createPrefix (const char className[], const char methodName[]) const

Post-construction modification routines
void	replaceGlobalValue (const GlobalOrdinal gblRow, const size_t col, const impl_scalar_type &value)
	Replace value in host memory, using global row index. More...
std::enable_if<!std::is_same < T, impl_scalar_type >::value &&std::is_convertible< T, impl_scalar_type >::value, void >::type	replaceGlobalValue (GlobalOrdinal globalRow, size_t col, const T &value)
	Like the above replaceGlobalValue, but only enabled if T differs from impl_scalar_type. More...
void	sumIntoGlobalValue (const GlobalOrdinal gblRow, const size_t col, const impl_scalar_type &value, const bool atomic=useAtomicUpdatesByDefault)
	Update (+=) a value in host memory, using global row index. More...
std::enable_if<!std::is_same < T, impl_scalar_type >::value &&std::is_convertible< T, impl_scalar_type >::value, void >::type	sumIntoGlobalValue (const GlobalOrdinal gblRow, const size_t col, const T &val, const bool atomic=useAtomicUpdatesByDefault)
	Like the above sumIntoGlobalValue, but only enabled if T differs from impl_scalar_type. More...
void	replaceLocalValue (const LocalOrdinal lclRow, const size_t col, const impl_scalar_type &value)
	Replace value in host memory, using local (row) index. More...
std::enable_if<!std::is_same < T, impl_scalar_type >::value &&std::is_convertible< T, impl_scalar_type >::value, void >::type	replaceLocalValue (const LocalOrdinal lclRow, const size_t col, const T &val)
	Like the above replaceLocalValue, but only enabled if T differs from impl_scalar_type. More...
void	sumIntoLocalValue (const LocalOrdinal lclRow, const size_t col, const impl_scalar_type &val, const bool atomic=useAtomicUpdatesByDefault)
	Update (+=) a value in host memory, using local row index. More...
std::enable_if<!std::is_same < T, impl_scalar_type >::value &&std::is_convertible< T, impl_scalar_type >::value, void >::type	sumIntoLocalValue (const LocalOrdinal lclRow, const size_t col, const T &val, const bool atomic=useAtomicUpdatesByDefault)
	Like the above sumIntoLocalValue, but only enabled if T differs from impl_scalar_type. More...
void	putScalar (const Scalar &value)
	Set all values in the multivector with the given value. More...
std::enable_if<!std::is_same < T, impl_scalar_type >::value &&std::is_convertible< T, impl_scalar_type >::value, void >::type	putScalar (const T &value)
	Set all values in the multivector with the given value. More...
void	randomize ()
	Set all values in the multivector to pseudorandom numbers. More...
void	randomize (const Scalar &minVal, const Scalar &maxVal)
	Set all values in the multivector to pseudorandom numbers in the given range. More...
void	replaceMap (const Teuchos::RCP< const map_type > &map)
	Replace the underlying Map in place. More...
void	reduce ()
	Sum values of a locally replicated multivector across all processes. More...
static const bool	useAtomicUpdatesByDefault
	Whether sumIntoLocalValue and sumIntoGlobalValue should use atomic updates by default. More...

Implementation of Tpetra::DistObject
bool	importsAreAliased ()
using	buffer_device_type = typename DistObject< scalar_type, local_ordinal_type, global_ordinal_type, node_type >::buffer_device_type
Kokkos::DualView < impl_scalar_type *, buffer_device_type >	unaliased_imports_
virtual bool	checkSizes (const SrcDistObject &sourceObj) override
	Whether data redistribution between sourceObj and this object is legal. More...
virtual size_t	constantNumberOfPackets () const override
	Number of packets to send per LID. More...
virtual void	copyAndPermute (const SrcDistObject &sourceObj, const size_t numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteFromLIDs, const CombineMode CM, const execution_space &space) override
virtual void	copyAndPermute (const SrcDistObject &sourceObj, const size_t numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &permuteFromLIDs, const CombineMode CM) override
virtual void	packAndPrepare (const SrcDistObject &sourceObj, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &exportLIDs, Kokkos::DualView< impl_scalar_type *, buffer_device_type > &exports, Kokkos::DualView< size_t *, buffer_device_type >, size_t &constantNumPackets, const execution_space &space) override
virtual void	packAndPrepare (const SrcDistObject &sourceObj, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &exportLIDs, Kokkos::DualView< impl_scalar_type *, buffer_device_type > &exports, Kokkos::DualView< size_t *, buffer_device_type >, size_t &constantNumPackets) override
virtual void	unpackAndCombine (const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &importLIDs, Kokkos::DualView< impl_scalar_type *, buffer_device_type > imports, Kokkos::DualView< size_t *, buffer_device_type >, const size_t constantNumPackets, const CombineMode CM, const execution_space &space) override
virtual void	unpackAndCombine (const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &importLIDs, Kokkos::DualView< impl_scalar_type *, buffer_device_type > imports, Kokkos::DualView< size_t *, buffer_device_type >, const size_t constantNumPackets, const CombineMode CM) override
virtual bool	reallocImportsIfNeeded (const size_t newSize, const bool verbose, const std::string *prefix, const bool areRemoteLIDsContiguous=false, const CombineMode CM=INSERT) override
	Reallocate imports_ if needed. More...

Detailed Description

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>
class Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >

A distributed dense vector.

Template Parameters

Scalar	The type of each entry of the vector. (You can use real-valued or complex-valued types here, unlike in Epetra, where the scalar type is always double.)
LocalOrdinal	The type of local indices. See the documentation of Map for requirements.
GlobalOrdinal	The type of global indices. See the documentation of Map for requirements.
Node	The Kokkos Node type. See the documentation of Map for requirements.

This class inherits from MultiVector, and has the same template parameters. A Vector is a special case of a MultiVector that has only one vector (column). It may be used wherever a MultiVector may be used. Please see the documentation of MultiVector for more details.

Definition at line 76 of file Tpetra_Vector_decl.hpp.

Member Typedef Documentation

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef Scalar Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::scalar_type

This class' first template parameter; the type of each entry in the Vector.

Definition at line 87 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::impl_scalar_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::impl_scalar_type

The type used internally in place of Scalar.

Some Scalar types might not work with Kokkos on all execution spaces, due to missing CUDA device macros or volatile overloads. The C++ standard type std::complex<T> has this problem. To fix this, we replace std::complex<T> values internally with the (usually) bitwise identical type Kokkos::complex<T>. The latter is the impl_scalar_type corresponding to Scalar = std::complex.

Definition at line 97 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef LocalOrdinal Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::local_ordinal_type

This class' second template parameter; the type of local indices.

Definition at line 99 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef GlobalOrdinal Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::global_ordinal_type

This class' third template parameter; the type of global indices.

Definition at line 101 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef Node::device_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::device_type

The Kokkos device type.

Definition at line 103 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef Node Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::node_type

The Kokkos Node type.

Definition at line 106 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::dot_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::dot_type

Type of an inner ("dot") product result.

This is usually the same as impl_scalar_type, but may differ if impl_scalar_type is e.g., an uncertainty quantification type from the Stokhos package.

Definition at line 113 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::mag_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::mag_type

Type of a norm result.

This is usually the same as the type of the magnitude (absolute value) of impl_scalar_type, but may differ if impl_scalar_type is e.g., an uncertainty quantification type from the Stokhos package.

Definition at line 121 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::dual_view_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::dual_view_type

Kokkos::DualView specialization used by this class.

Definition at line 124 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::wrapped_dual_view_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::wrapped_dual_view_type

WrappedDualView specialization used by this class.

Definition at line 127 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

typedef base_type::map_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::map_type

The type of the Map specialization used by this class.

Definition at line 130 of file Tpetra_Vector_decl.hpp.

using Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::execution_space = typename device_type::execution_space

inherited

Type of the (new) Kokkos execution space.

The execution space implements parallel operations, like parallel_for, parallel_reduce, and parallel_scan.

Definition at line 443 of file Tpetra_MultiVector_decl.hpp.

using Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::packet_type = typename ::Kokkos::ArithTraits<Scalar >::val_type

inherited

The type of each datum being sent or received in an Import or Export.

Note that this type does not always correspond to the Scalar template parameter of subclasses.

Definition at line 334 of file Tpetra_DistObject_decl.hpp.

Constructor & Destructor Documentation

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector

(

)

Default constructor: makes a Vector with no rows or columns.

Definition at line 58 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector ( const Teuchos::RCP< const map_type > &  map, const bool  zeroOut = true  )

explicit

Basic constructor.

Parameters

map	[in] The Vector's Map. The Map describes the distribution of rows over process(es) in the Map's communicator.
zeroOut	[in] If true (the default), require that all the Vector's entries be zero on return. If false, the Vector's entries have undefined values on return, and must be set explicitly.

Definition at line 64 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &	source,
		const Teuchos::DataAccess	copyOrView
	)

Copy constructor (shallow or deep copy).

Parameters

source	[in] The Vector to copy.
copyOrView	[in] If Teuchos::View, return a shallow copy (a view) of source. If Teuchos::Copy, return a deep copy of source. Regardless, the result has "view semantics." This means that copy construction or assignment (operator=) with the resulting object will always do a shallow copy, and will transmit view semantics to the result of the shallow copy.

Definition at line 71 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &	source,
		const Teuchos::RCP< const map_type > &	map,
		const local_ordinal_type	rowOffset = 0
	)

"Offset view" constructor that views the input Vector's local data, but with the given Map, using the given row offset.

Parameters

source	[in] The Vector to view.
map	[in] The Map to use to interpret the local data.

Definition at line 78 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Teuchos::RCP< const map_type > &	map,
		const Teuchos::ArrayView< const Scalar > &	A
	)

Set vector values from an existing array (copy)

Definition at line 86 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Teuchos::RCP< const map_type > &	map,
		const dual_view_type &	view
	)

Expert mode constructor, that takes a Kokkos::DualView of the Vector's data, and returns a Vector that views those data.

Warning

This constructor is only for expert users. We make no promises about backwards compatibility for this interface. It may change or go away at any time.

See the documentation of the MultiVector (parent class) constructor that takes the same arguments.

Parameters

map	[in] Map describing the distribution of rows.
view	[in] View of the data (shallow copy).

Definition at line 93 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Teuchos::RCP< const map_type > &	map,
		const dual_view_type &	view,
		const dual_view_type &	origView
	)

Expert mode constructor, that takes a Kokkos::DualView of the Vector's data and the "original" Kokkos::DualView of the data, and returns a Vector that views those data.

Warning

This constructor is only for expert users. We make no promises about backwards compatibility for this interface. It may change or go away at any time.

See the documentation of the MultiVector (parent class) constructor that takes the same arguments.

Parameters

map	[in] Map describing the distribution of rows.
view	[in] View of the data (shallow copy).
origView	[in] "Original" view of the data (shallow copy).

Definition at line 100 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const Teuchos::RCP< const map_type > &	map,
		const wrapped_dual_view_type &	d_view
	)

Expert mode constructor, that takes a WrappedDualView of the MultiVector's data.

Warning

This constructor is only for expert users. We make no promises about backwards compatibility for this interface. It may change or go away at any time. It is mainly useful for Tpetra developers and we do not expect it to be useful for anyone else.

Definition at line 109 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector	(	const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &	X,
		const size_t	j
	)

Create a Vector that views a single column of the input MultiVector.

Parameters

X	[in] Input MultiVector to view (in possibly nonconst fashion).
j	[in] The column of X to view.

Definition at line 116 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector ( const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  )

default

Copy constructor (shallow copy).

Vector's copy constructor always does a shallow copy. Use the nonmember function Tpetra::deep_copy (see Tpetra_MultiVector_decl.hpp) to deep-copy one existing Vector to another, and use the two-argument "copy constructor" below (with copyOrView=Teuchos::Copy) to create a Vector that is a deep copy of an existing Vector.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::Vector ( Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &&  )

default

Move constructor (shallow move).

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

virtual Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::~Vector ( )

virtualdefault

Destructor (virtual for memory safety of derived classes).

Note

To Tpetra developers: See the C++ Core Guidelines C.21 ("If you define or <tt>=delete</tt> any default operation, define or <tt>=delete</tt> them all"), in particular the AbstractBase example, for why this destructor declaration implies that we need the above four =default declarations for copy construction, move construction, copy assignment, and move assignment.

Member Function Documentation

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Vector& Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::operator= ( const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  )

default

Copy assignment (shallow copy).

Vector's copy assignment operator always does a shallow copy. Use the nonmember function Tpetra::deep_copy (see Tpetra_MultiVector_decl.hpp) to deep-copy one existing Vector to another.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Vector<Scalar, LocalOrdinal, GlobalOrdinal, Node>& Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::operator= ( Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &&  )

default

Move assigment (shallow move).

template<class Scalar, class LocalOrdinal , class GlobalOrdinal, class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::replaceGlobalValue	(	const GlobalOrdinal	globalRow,
		const Scalar &	value
	)

Replace current value at the specified location with specified value.

Precondition

globalRow must be a valid global element on this node, according to the row map.

Definition at line 124 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal , class GlobalOrdinal, class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::sumIntoGlobalValue	(	const GlobalOrdinal	globalRow,
		const Scalar &	value,
		const bool	atomic = base_type::useAtomicUpdatesByDefault
	)

Add value to existing value, using global (row) index.

Add the given value to the existing value at row globalRow (a global index).

This method affects the host memory version of the data. If the DeviceType template parameter is a device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation.

Parameters

globalRow	[in] Global row index of the entry to modify. This must be a valid global row index on the calling process with respect to the Vector's Map.
value	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

Definition at line 131 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal , class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::replaceLocalValue	(	const LocalOrdinal	myRow,
		const Scalar &	value
	)

Replace current value at the specified location with specified values.

Precondition

localRow must be a valid local element on this node, according to the row map.

Definition at line 141 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal , class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::sumIntoLocalValue	(	const LocalOrdinal	myRow,
		const Scalar &	value,
		const bool	atomic = base_type::useAtomicUpdatesByDefault
	)

Add value to existing value, using local (row) index.

Add the given value to the existing value at row localRow (a local index).

This method affects the host memory version of the data. If the DeviceType template parameter is a device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation.

Parameters

localRow	[in] Local row index of the entry to modify.
value	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

Definition at line 148 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal , class GlobalOrdinal , class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::get1dCopy

(

const Teuchos::ArrayView< Scalar > &

A

)

const

Return multi-vector values in user-provided two-dimensional array (using Teuchos memory management classes).

Definition at line 158 of file Tpetra_Vector_def.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Teuchos::ArrayRCP<Scalar> Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::getDataNonConst ( )

inline

View of the local values of this vector.

Definition at line 338 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Teuchos::ArrayRCP<const Scalar> Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::getData ( ) const

inline

Const view of the local values of this vector.

Definition at line 344 of file Tpetra_Vector_decl.hpp.

template<class Scalar, class LocalOrdinal, class GlobalOrdinal, class Node>

Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::dot_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::dot

(

const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &

y

)

const

Return the dot product of this Vector and the input Vector x.

Definition at line 166 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::mag_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::norm1

(

)

const

Return the one-norm of this Vector.

Definition at line 186 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::mag_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::norm2

(

)

const

Return the two-norm of this Vector.

Definition at line 196 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::mag_type Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::normInf

(

)

const

Return the infinity-norm of this Vector.

Definition at line 206 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Scalar Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::meanValue

(

)

const

Compute mean (average) value of this Vector.

Definition at line 176 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

std::string Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::description ( ) const

virtual

Return a one-line description of this object.

Reimplemented from Tpetra::MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node >.

Definition at line 216 of file Tpetra_Vector_def.hpp.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

void Tpetra::Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node >::describe ( Teuchos::FancyOStream &  out, const Teuchos::EVerbosityLevel  verbLevel = Teuchos::Describable::verbLevel_default  ) const

virtual

Describe this object in a human-readable way to the given output stream.

You must call this method as a collective over all processes in this object's communicator.

Parameters

out	[out] Output stream to which to write. Only Process 0 in this object's communicator may write to the output stream.
verbLevel	[in] Verbosity level. This also controls whether this method does any communication. At verbosity levels higher (greater) than Teuchos::VERB_LOW, this method may behave as a collective over the object's communicator.

Teuchos::FancyOStream wraps std::ostream. It adds features like tab levels. If you just want to wrap std::cout, try this:

auto out = Teuchos::getFancyOStream (Teuchos::rcpFromRef (std::out));

Reimplemented from Tpetra::MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node >.

Definition at line 223 of file Tpetra_Vector_def.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::swap ( MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  mv )

inherited

Swap contents of mv with contents of *this.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::replaceGlobalValue ( const GlobalOrdinal  gblRow, const size_t  col, const impl_scalar_type &  value  )

inherited

Replace value in host memory, using global row index.

Replace the current value at row gblRow (a global index) and column col with the given value. The column index is zero based.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

This method does not have an "atomic" option like sumIntoGlobalValue. This is deliberate. Replacement is not commutative, unlike += (modulo rounding error). Concurrent calls to replaceGlobalValue on different threads that modify the same entry/ies have undefined results. (It's not just that one thread might win; it's that the value might get messed up.)

Parameters

gblRow	[in] Global row index of the entry to modify. This must be a valid global row index on the calling process with respect to the MultiVector's Map.
col	[in] Column index of the entry to modify.
value	[in] Incoming value to add to the entry.

std::enable_if<! std::is_same<T, impl_scalar_type>::value && std::is_convertible<T, impl_scalar_type>::value, void>::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::replaceGlobalValue ( GlobalOrdinal  globalRow, size_t  col, const T &  value  )

inlineinherited

Like the above replaceGlobalValue, but only enabled if T differs from impl_scalar_type.

This method only exists if its template parameter T and impl_scalar_type differ, and if it is syntactically possible to convert T to impl_scalar_type. This method is mainly useful for backwards compatibility, when the Scalar template parameter differs from impl_scalar_type. That is commonly only the case when Scalar is std::complex<U> for some type U.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

This method does not have an "atomic" option like sumIntoGlobalValue. This is deliberate. Replacement is not commutative, unlike += (modulo rounding error). Concurrent calls to replaceGlobalValue on different threads that modify the same entry/ies have undefined results. (It's not just that one thread might win; it's that the value might get messed up.)

Parameters

gblRow	[in] Global row index of the entry to modify. This must be a valid global row index on the calling process with respect to the MultiVector's Map.
col	[in] Column index of the entry to modify.
value	[in] Incoming value to add to the entry.

Definition at line 920 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::sumIntoGlobalValue ( const GlobalOrdinal  gblRow, const size_t  col, const impl_scalar_type &  value, const bool  atomic = useAtomicUpdatesByDefault  )

inherited

Update (+=) a value in host memory, using global row index.

Add the given value to the existing value at row gblRow (a global index) and column col. The column index is zero based.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

Parameters

gblRow	[in] Global row index of the entry to modify. This must be a valid global row index on the calling process with respect to the MultiVector's Map.
col	[in] Column index of the entry to modify.
value	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

std::enable_if<! std::is_same<T, impl_scalar_type>::value && std::is_convertible<T, impl_scalar_type>::value, void>::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::sumIntoGlobalValue ( const GlobalOrdinal  gblRow, const size_t  col, const T &  val, const bool  atomic = useAtomicUpdatesByDefault  )

inlineinherited

Like the above sumIntoGlobalValue, but only enabled if T differs from impl_scalar_type.

This method only exists if its template parameter T and impl_scalar_type differ, and if it is syntactically possible to convert T to impl_scalar_type. This method is mainly useful for backwards compatibility, when the Scalar template parameter differs from impl_scalar_type. That is commonly only the case when Scalar is std::complex<U> for some type U.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

Parameters

gblRow	[in] Global row index of the entry to modify. This must be a valid global row index on the calling process with respect to the MultiVector's Map.
col	[in] Column index of the entry to modify.
val	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

Definition at line 987 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::replaceLocalValue ( const LocalOrdinal  lclRow, const size_t  col, const impl_scalar_type &  value  )

inherited

Replace value in host memory, using local (row) index.

Replace the current value at row lclRow (a local index) and column col with the given value. The column index is zero based.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

This method does not have an "atomic" option like sumIntoLocalValue. This is deliberate. Replacement is not commutative, unlike += (modulo rounding error). Concurrent calls to replaceLocalValue on different threads that modify the same entry/ies have undefined results. (It's not just that one thread might win; it's that the value might get messed up.)

Parameters

lclRow	[in] Local row index of the entry to modify. Must be a valid local index in this MultiVector's Map on the calling process.
col	[in] Column index of the entry to modify.
value	[in] Incoming value to add to the entry.

std::enable_if<! std::is_same<T, impl_scalar_type>::value && std::is_convertible<T, impl_scalar_type>::value, void>::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::replaceLocalValue ( const LocalOrdinal  lclRow, const size_t  col, const T &  val  )

inlineinherited

Like the above replaceLocalValue, but only enabled if T differs from impl_scalar_type.

This method only exists if its template parameter T and impl_scalar_type differ, and if it is syntactically possible to convert T to impl_scalar_type. This method is mainly useful for backwards compatibility, when the Scalar template parameter differs from impl_scalar_type. That is commonly only the case when Scalar is std::complex<U> for some type U.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

This method does not have an "atomic" option like sumIntoLocalValue. This is deliberate. Replacement is not commutative, unlike += (modulo rounding error). Concurrent calls to replaceLocalValue on different threads that modify the same entry/ies have undefined results. (It's not just that one thread might win; it's that the value might get messed up.)

Parameters

lclRow	[in] Local row index of the entry to modify. Must be a valid local index in this MultiVector's Map on the calling process.
col	[in] Column index of the entry to modify.
val	[in] Incoming value to add to the entry.

Definition at line 1064 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::sumIntoLocalValue ( const LocalOrdinal  lclRow, const size_t  col, const impl_scalar_type &  val, const bool  atomic = useAtomicUpdatesByDefault  )

inherited

Update (+=) a value in host memory, using local row index.

Add the given value to the existing value at row localRow (a local index) and column col. The column index is zero based.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

Parameters

lclRow	[in] Local row index of the entry to modify. Must be a valid local index in this MultiVector's Map on the calling process.
col	[in] Column index of the entry to modify.
val	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

std::enable_if<! std::is_same<T, impl_scalar_type>::value && std::is_convertible<T, impl_scalar_type>::value, void>::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::sumIntoLocalValue ( const LocalOrdinal  lclRow, const size_t  col, const T &  val, const bool  atomic = useAtomicUpdatesByDefault  )

inlineinherited

Like the above sumIntoLocalValue, but only enabled if T differs from impl_scalar_type.

This method only exists if its template parameter T and impl_scalar_type differ, and if it is syntactically possible to convert T to impl_scalar_type. This method is mainly useful for backwards compatibility, when the Scalar template parameter differs from impl_scalar_type. That is commonly only the case when Scalar is std::complex<U> for some type U.

This method affects the host memory version of the data. If device_type is a Kokkos device that has two memory spaces, and you want to modify the non-host version of the data, you must access the device View directly by calling getLocalView(). Please see modify(), sync(), and the discussion of DualView semantics elsewhere in the documentation. This method calls sync_host() before modifying host data, and modify_host() afterwards.

Parameters

lclRow	[in] Local row index of the entry to modify.
col	[in] Column index of the entry to modify.
val	[in] Incoming value to add to the entry.
atomic	[in] Whether to use an atomic update. If this class' execution space is not Kokkos::Serial, then this is true by default, else it is false by default.

Definition at line 1129 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::putScalar ( const Scalar &  value )

inherited

Set all values in the multivector with the given value.

std::enable_if<! std::is_same<T, impl_scalar_type>::value && std::is_convertible<T, impl_scalar_type>::value, void>::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::putScalar ( const T &  value )

inlineinherited

Set all values in the multivector with the given value.

This method only exists if its template parameter T and impl_scalar_type differ, and if it is syntactically possible to convert T to impl_scalar_type. This method is mainly useful for backwards compatibility, when the Scalar template parameter differs from impl_scalar_type. That is commonly only the case when Scalar is std::complex<U> for some type U.

Definition at line 1150 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::randomize ( )

inherited

Set all values in the multivector to pseudorandom numbers.

Note

Do not expect repeatable results.

Behavior of this method may or may not depend on external use of the C library routines srand() and rand(). In particular, setting the seed there may not affect it here.

Warning

This method does not promise to use a distributed-memory parallel pseudorandom number generator. Corresponding values on different processes might be correlated. It also does not promise to use a high-quality pseudorandom number generator within each process.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::randomize ( const Scalar &  minVal, const Scalar &  maxVal  )

inherited

Set all values in the multivector to pseudorandom numbers in the given range.

Note

Do not expect repeatable results.

Behavior of this method may or may not depend on external use of the C library routines srand() and rand(). In particular, setting the seed there may not affect it here.

Warning

This method does not promise to use a distributed-memory parallel pseudorandom number generator. Corresponding values on different processes might be correlated. It also does not promise to use a high-quality pseudorandom number generator within each process.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::replaceMap ( const Teuchos::RCP< const map_type > &  map )

inherited

Replace the underlying Map in place.

Warning

The normal use case of this method, with an input Map that is compatible with the object's current Map and has the same communicator, is safe. However, if the input Map has a different communicator (with a different number of processes, in particular) than this object's current Map, the semantics of this method are tricky. We recommend that only experts try the latter use case.

Precondition

If the new Map's communicator is similar to the original Map's communicator, then the original Map and new Map must be compatible: map->isCompatible (this->getMap ()). "Similar" means that the communicators have the same number of processes, though these need not be in the same order (have the same assignments of ranks) or represent the same communication contexts. It means the same thing as the MPI_SIMILAR return value of MPI_COMM_COMPARE. See MPI 3.0 Standard, Section 6.4.1.

If the new Map's communicator contains more processes than the original Map's communicator, then the projection of the original Map onto the new communicator must be compatible with the new Map.

If the new Map's communicator contains fewer processes than the original Map's communicator, then the projection of the new Map onto the original communicator must be compatible with the original Map.

This method replaces this object's Map with the given Map. This relabels the rows of the multivector using the global IDs in the input Map. Thus, it implicitly applies a permutation, without actually moving data. If the new Map's communicator has more processes than the original Map's communicator, it "projects" the MultiVector onto the new Map by filling in missing rows with zeros. If the new Map's communicator has fewer processes than the original Map's communicator, the method "forgets about" any rows that do not exist in the new Map. (It mathematical terms, if one considers a MultiVector as a function from one vector space to another, this operation restricts the range.)

This method must always be called collectively on the communicator with the largest number of processes: either this object's current communicator (this->getMap()->getComm()), or the new Map's communicator (map->getComm()). If the new Map's communicator has fewer processes, then the new Map must be null on processes excluded from the original communicator, and the current Map must be nonnull on all processes. If the new Map has more processes, then it must be nonnull on all those processes, and the original Map must be null on those processes which are not in the new Map's communicator. (The latter case can only happen to a MultiVector to which a replaceMap() operation has happened before.)

Warning

This method must always be called as a collective operation on all processes in the original communicator (this->getMap ()->getComm ()). We reserve the right to do checking in debug mode that requires this method to be called collectively in order not to deadlock.

Note

This method does not do data redistribution. If you need to move data around, use Import or Export.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::reduce ( )

inherited

Sum values of a locally replicated multivector across all processes.

Warning

This method may only be called for locally replicated MultiVectors.

Precondition

isDistributed() == false

Teuchos::RCP<MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subCopy ( const Teuchos::Range1D &  colRng ) const

inherited

Return a MultiVector with copies of selected columns.

Teuchos::RCP<MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subCopy ( const Teuchos::ArrayView< const size_t > &  cols ) const

inherited

Return a MultiVector with copies of selected columns.

Teuchos::RCP<const MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subView ( const Teuchos::Range1D &  colRng ) const

inherited

Return a const MultiVector with const views of selected columns.

Teuchos::RCP<const MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subView ( const Teuchos::ArrayView< const size_t > &  cols ) const

inherited

Return a const MultiVector with const views of selected columns.

Teuchos::RCP<MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subViewNonConst ( const Teuchos::Range1D &  colRng )

inherited

Return a MultiVector with views of selected columns.

Teuchos::RCP<MultiVector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::subViewNonConst ( const Teuchos::ArrayView< const size_t > &  cols )

inherited

Return a MultiVector with views of selected columns.

Teuchos::RCP<const Vector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getVector ( const size_t  j ) const

inherited

Return a Vector which is a const view of column j.

Teuchos::RCP<Vector<Scalar, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getVectorNonConst ( const size_t  j )

inherited

Return a Vector which is a nonconst view of column j.

Teuchos::ArrayRCP<const Scalar> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getData ( size_t  j ) const

inherited

Const view of the local values in a particular vector of this multivector.

Teuchos::ArrayRCP<Scalar> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getDataNonConst ( size_t  j )

inherited

View of the local values in a particular vector of this multivector.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get1dCopy ( const Teuchos::ArrayView< Scalar > &  A, const size_t  LDA  ) const

inherited

Fill the given array with a copy of this multivector's local values.

Parameters

A	[out] View of the array to fill. We consider A as a matrix with column-major storage.
LDA	[in] Leading dimension of the matrix A.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get2dCopy ( const Teuchos::ArrayView< const Teuchos::ArrayView< Scalar > > &  ArrayOfPtrs ) const

inherited

Fill the given array with a copy of this multivector's local values.

Parameters

ArrayOfPtrs

[out] Array of arrays, one for each column of the multivector. On output, we fill ArrayOfPtrs[j] with the data for column j of this multivector.

Teuchos::ArrayRCP<const Scalar> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get1dView ( ) const

inherited

Const persisting (1-D) view of this multivector's local values.

This method assumes that the columns of the multivector are stored contiguously. If not, this method throws std::runtime_error.

Teuchos::ArrayRCP<Teuchos::ArrayRCP<const Scalar> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get2dView ( ) const

inherited

Return const persisting pointers to values.

Teuchos::ArrayRCP<Scalar> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get1dViewNonConst ( )

inherited

Nonconst persisting (1-D) view of this multivector's local values.

This method assumes that the columns of the multivector are stored contiguously. If not, this method throws std::runtime_error.

Teuchos::ArrayRCP<Teuchos::ArrayRCP<Scalar> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::get2dViewNonConst ( )

inherited

Return non-const persisting pointers to values.

dual_view_type::t_host::const_type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewHost ( Access::ReadOnlyStruct  ) const

inherited

Return a read-only, up-to-date view of this MultiVector's local data on host. This requires that there are no live device-space views.

dual_view_type::t_host Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewHost ( Access::ReadWriteStruct  )

inherited

Return a mutable, up-to-date view of this MultiVector's local data on host. This requires that there are no live device-space views.

dual_view_type::t_host Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewHost ( Access::OverwriteAllStruct  )

inherited

Return a mutable view of this MultiVector's local data on host, assuming all existing data will be overwritten. This requires that there are no live device-space views.

dual_view_type::t_dev::const_type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewDevice ( Access::ReadOnlyStruct  ) const

inherited

Return a read-only, up-to-date view of this MultiVector's local data on device. This requires that there are no live host-space views.

dual_view_type::t_dev Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewDevice ( Access::ReadWriteStruct  )

inherited

Return a mutable, up-to-date view of this MultiVector's local data on device. This requires that there are no live host-space views.

dual_view_type::t_dev Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalViewDevice ( Access::OverwriteAllStruct  )

inherited

Return a mutable view of this MultiVector's local data on device, assuming all existing data will be overwritten. This requires that there are no live host-space views.

wrapped_dual_view_type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getWrappedDualView ( ) const

inherited

Return the wrapped dual view holding this MultiVector's local data.

Warning

This method is ONLY for use by experts. We highly recommend accessing the local data by using the member functions getLocalViewHost and getLocalViewDevice.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::need_sync ( ) const

inlineinherited

Whether this MultiVector needs synchronization to the given space.

Definition at line 1485 of file Tpetra_MultiVector_decl.hpp.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::need_sync_host ( ) const

inherited

Whether this MultiVector needs synchronization to the host.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::need_sync_device ( ) const

inherited

Whether this MultiVector needs synchronization to the device.

std::remove_reference<decltype(std::declval<dual_view_type>).template view<TargetDeviceType>))>::type::const_type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalView ( Access::ReadOnlyStruct  s ) const

inlineinherited

Return a view of the local data on a specific device, with the given access mode. The return type is either dual_view_type::t_dev, dual_view_type::t_host, or the const_type of one of those.

Template Parameters

TargetDeviceType

The Kokkos Device type whose data to return.

For example, suppose you create a Tpetra::MultiVector for the Kokkos::Cuda device, like this:

typedef Tpetra::KokkosCompat::KokkosDeviceWrapperNode<Kokkos::Cuda> > node_type;
typedef Tpetra::Map<int, int, node_type> map_type;
typedef Tpetra::MultiVector<float, int, int, node_type> mv_type;

RCP<const map_type> map = ...;
mv_type DV (map, 3);

If you want to get the CUDA device Kokkos::View as read-write, do this:

typedef typename mv_type::dual_view_type dual_view_type;
typedef typename dual_view_type::t_dev device_view_type;
device_view_type cudaView = DV.getLocalView<Kokkos::Cuda> (Access::ReadWrite);

and if you want to get the host mirror of that View, do this:

typedef typename dual_view_type::host_mirror_space host_execution_space;
typedef typename dual_view_type::t_host host_view_type;
host_view_type hostView = DV.getLocalView<host_execution_space> (Access::ReadWrite);

Definition at line 1525 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::dot ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Teuchos::ArrayView< dot_type > &  dots  ) const

inherited

Compute the dot product of each corresponding pair of vectors (columns) in A and B.

The "dot product" is the standard Euclidean inner product. If the type of entries of the vectors (impl_scalar_type) is complex, then A is transposed, not *this. For example, if x and y each have one column, then x.dot (y, dots) computes .

Precondition

*this and A have the same number of columns (vectors).

dots has at least as many entries as the number of columns in A.

Postcondition

dots[j] == (this->getVector[j])->dot (* (A.getVector[j]))

std::enable_if< ! (std::is_same<dot_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::dot ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Teuchos::ArrayView< T > &  dots  ) const

inlineinherited

Compute the dot product of each corresponding pair of vectors (columns) in A and B.

Template Parameters

T	The output type of the dot products.

This method only exists if dot_type and T are different types. For example, if impl_scalar_type and dot_type differ, then this method ensures backwards compatibility with the previous interface (that returned dot products as impl_scalar_type rather than as dot_type). The complicated enable_if expression just ensures that the method only exists if dot_type and T are different types; the method still returns void, as above.

Definition at line 1579 of file Tpetra_MultiVector_decl.hpp.

std::enable_if< ! (std::is_same<dot_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::dot ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, std::vector< T > &  dots  ) const

inlineinherited

Like the above dot() overload, but for std::vector output.

Definition at line 1594 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::dot ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Kokkos::View< dot_type *, Kokkos::HostSpace > &  norms  ) const

inherited

Compute the dot product of each corresponding pair of vectors (columns) in A and B, storing the result in a device View.

The "dot product" is the standard Euclidean inner product. If the type of entries of the vectors (impl_scalar_type) is complex, then A is transposed, not *this. For example, if x and y each have one column, then x.dot (y, dots) computes .

Parameters

A	[in] MultiVector with which to dot *this.
dots	[out] Device View with getNumVectors() entries.

Precondition

this->getNumVectors () == A.getNumVectors ()

dots.extent (0) == A.getNumVectors ()

Postcondition

dots(j) == (this->getVector[j])->dot (* (A.getVector[j]))

std::enable_if< ! (std::is_same<dot_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::dot ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Kokkos::View< T *, device_type > &  dots  ) const

inlineinherited

Compute the dot product of each corresponding pair of vectors (columns) in A and B, storing the result in a device view.

Template Parameters

T	The output type of the dot products.

This method only exists if dot_type and T are different types. For example, if Scalar and dot_type differ, then this method ensures backwards compatibility with the previous interface (that returned dot products as Scalar rather than as dot_type). The complicated enable_if expression just ensures that the method only exists if dot_type and T are different types; the method still returns void, as above.

Definition at line 1653 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::abs ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A )

inherited

Put element-wise absolute values of input Multi-vector in target: A = abs(this)

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::reciprocal ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A )

inherited

Put element-wise reciprocal values of input Multi-vector in target, this(i,j) = 1/A(i,j).

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::scale ( const Scalar &  alpha )

inherited

Scale in place: this = alpha*this.

Replace this MultiVector with alpha times this MultiVector. This method will always multiply, even if alpha is zero. That means, for example, that if *this contains NaN entries before calling this method, the NaN entries will remain after this method finishes.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::scale ( const Teuchos::ArrayView< const Scalar > &  alpha )

inherited

Scale each column in place: this[j] = alpha[j]*this[j].

Replace each column j of this MultiVector with alpha[j] times the current column j of this MultiVector. This method will always multiply, even if all the entries of alpha are zero. That means, for example, that if *this contains NaN entries before calling this method, the NaN entries will remain after this method finishes.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::scale ( const Kokkos::View< const impl_scalar_type *, device_type > &  alpha )

inherited

Scale each column in place: this[j] = alpha[j]*this[j].

Replace each column j of this MultiVector with alpha[j] times the current column j of this MultiVector. This method will always multiply, even if all the entries of alpha are zero. That means, for example, that if *this contains NaN entries before calling this method, the NaN entries will remain after this method finishes.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::scale ( const Scalar &  alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A  )

inherited

Scale in place: this = alpha * A.

Replace this MultiVector with scaled values of A. This method will always multiply, even if alpha is zero. That means, for example, that if *this contains NaN entries before calling this method, the NaN entries will remain after this method finishes. It is legal for the input A to alias this MultiVector.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::update ( const Scalar &  alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Scalar &  beta  )

inherited

Update: this = beta*this + alpha*A.

Update this MultiVector with scaled values of A. If beta is zero, overwrite *this unconditionally, even if it contains NaN entries. It is legal for the input A to alias this MultiVector.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::update ( const Scalar &  alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const Scalar &  beta, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  B, const Scalar &  gamma  )

inherited

Update: this = gamma*this + alpha*A + beta*B.

Update this MultiVector with scaled values of A and B. If gamma is zero, overwrite *this unconditionally, even if it contains NaN entries. It is legal for the inputs A or B to alias this MultiVector.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm1 ( const Kokkos::View< mag_type *, Kokkos::HostSpace > &  norms ) const

inherited

Compute the one-norm of each vector (column), storing the result in a host view.

Parameters

norms

[out] Host View with getNumVectors() entries.

Precondition

norms.extent (0) == this->getNumVectors ()

Postcondition

norms(j) == (this->getVector[j])->norm1 (* (A.getVector[j]))

The one-norm of a vector is the sum of the magnitudes of the vector's entries. On exit, norms(j) is the one-norm of column j of this MultiVector.

std::enable_if< ! (std::is_same<mag_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm1 ( const Kokkos::View< T *, device_type > &  norms ) const

inlineinherited

Compute the one-norm of each vector (column), storing the result in a device view.

Template Parameters

T	The output type of the dot products.

See the above norm1() method for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms products as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 1787 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm1 ( const Teuchos::ArrayView< mag_type > &  norms ) const

inherited

Compute the one-norm of each vector (column).

See the uppermost norm1() method above for documentation.

std::enable_if< ! (std::is_same<mag_type,T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm1 ( const Teuchos::ArrayView< T > &  norms ) const

inlineinherited

Compute the one-norm of each vector (column).

Template Parameters

T	The output type of the norms.

See the uppermost norm1() method above for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 1823 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm2 ( const Kokkos::View< mag_type *, Kokkos::HostSpace > &  norms ) const

inherited

Compute the two-norm of each vector (column), storing the result in a host View.

Parameters

norms

[out] Host View with getNumVectors() entries.

Precondition

norms.extent (0) == this->getNumVectors ()

Postcondition

norms(j) == (this->getVector[j])->dot (* (A.getVector[j]))

The two-norm of a vector is the standard Euclidean norm, the square root of the sum of squares of the magnitudes of the vector's entries. On exit, norms(k) is the two-norm of column k of this MultiVector.

std::enable_if< ! (std::is_same<mag_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm2 ( const Kokkos::View< T *, device_type > &  norms ) const

inlineinherited

Compute the two-norm of each vector (column), storing the result in a device view.

See the above norm2() method for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 1879 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm2 ( const Teuchos::ArrayView< mag_type > &  norms ) const

inherited

Compute the two-norm of each vector (column).

See the uppermost norm2() method above for documentation.

std::enable_if< ! (std::is_same<mag_type,T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::norm2 ( const Teuchos::ArrayView< T > &  norms ) const

inlineinherited

Compute the two-norm of each vector (column).

Template Parameters

T	The output type of the norms.

See the uppermost norm2() method above for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms products as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 1915 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::normInf ( const Kokkos::View< mag_type *, Kokkos::HostSpace > &  norms ) const

inherited

Compute the infinity-norm of each vector (column), storing the result in a host View.

The infinity-norm of a vector is the maximum of the magnitudes of the vector's entries. On exit, norms(j) is the infinity-norm of column j of this MultiVector.

std::enable_if< ! (std::is_same<mag_type, T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::normInf ( const Kokkos::View< T *, device_type > &  norms ) const

inlineinherited

Compute the infinity-norm of each vector (column), storing the result in a device view.

See the above normInf() method for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 1964 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::normInf ( const Teuchos::ArrayView< mag_type > &  norms ) const

inherited

Compute the infinity-norm of each vector (column), storing the result in a Teuchos::ArrayView.

See the uppermost normInf() method above for documentation.

std::enable_if< ! (std::is_same<mag_type,T>::value), void >::type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::normInf ( const Teuchos::ArrayView< T > &  norms ) const

inlineinherited

Compute the infinity-norm of each vector (column), storing the result in a Teuchos::ArrayView.

Template Parameters

T	The output type of the norms.

See the uppermost normInf() method above for documentation.

This method only exists if mag_type and T are different types. For example, if Teuchos::ScalarTraits<Scalar>::magnitudeType and mag_type differ, then this method ensures backwards compatibility with the previous interface (that returned norms products as Teuchos::ScalarTraits<Scalar>::magnitudeType rather than as mag_type). The complicated enable_if expression just ensures that the method only exists if mag_type and T are different types; the method still returns void, as above.

Definition at line 2002 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::meanValue ( const Teuchos::ArrayView< impl_scalar_type > &  means ) const

inherited

Compute mean (average) value of each column.

The outcome of this routine is undefined for non-floating point scalar types (e.g., int).

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::multiply ( Teuchos::ETransp  transA, Teuchos::ETransp  transB, const Scalar &  alpha, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  B, const Scalar &  beta  )

inherited

Matrix-matrix multiplication: this = beta*this + alpha*op(A)*op(B).

If beta is zero, overwrite *this unconditionally, even if it contains NaN entries. This imitates the semantics of analogous BLAS routines like DGEMM.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::elementWiseMultiply ( Scalar  scalarAB, const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  A, const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  B, Scalar  scalarThis  )

inherited

Multiply a Vector A elementwise by a MultiVector B.

Compute this = scalarThis * this + scalarAB * B @ A where </tt> denotes element-wise multiplication. In pseudocode, if C denotes *this MultiVector:

C(i,j) = scalarThis * C(i,j) + scalarAB * B(i,j) * A(i,1);

for all rows i and columns j of C.

B must have the same dimensions as *this, while A must have the same number of rows but a single column.

We do not require that A, B, and *this have compatible Maps, as long as the number of rows in A, B, and *this on each process is the same. For example, one or more of these vectors might have a locally replicated Map, or a Map with a local communicator (MPI_COMM_SELF). This case may occur in block relaxation algorithms when applying a diagonal scaling.

size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getNumVectors ( ) const

inherited

Number of columns in the multivector.

size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getLocalLength ( ) const

inherited

Local number of rows on the calling process.

global_size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getGlobalLength ( ) const

inherited

Global number of rows in the multivector.

size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getStride ( ) const

inherited

Stride between columns in the multivector.

This is only meaningful if isConstantStride() returns true.

Warning

This may be different on different processes.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::isConstantStride ( ) const

inherited

Whether this multivector has constant stride between columns.

Warning

This may be different on different processes.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::aliases ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  other ) const

inherited

Whether this multivector's memory might alias other. This is conservative: if either this or other is not constant stride, then it simply checks whether the contiguous memory allocations overlap. It doesn't check whether the sets of columns overlap. This is a symmetric relation: X.aliases(Y) == Y.aliases(X).

virtual void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::removeEmptyProcessesInPlace ( const Teuchos::RCP< const map_type > &  newMap )

overridevirtualinherited

Remove processes owning zero rows from the Map and their communicator.

Warning

This method is ONLY for use by experts. We highly recommend using the nonmember function of the same name defined in Tpetra_DistObject_decl.hpp.

We make NO promises of backwards compatibility. This method may change or disappear at any time.

Parameters

newMap

[in] This must be the result of calling the removeEmptyProcesses() method on the row Map. If it is not, this method's behavior is undefined. This pointer will be null on excluded processes.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::removeEmptyProcessesInPlace ( const Teuchos::RCP< const map_type > &  newMap )

virtualinherited

Remove processes which contain no entries in this object's Map.

Warning

This method is ONLY for use by experts. We highly recommend using the nonmember function of the same name defined in this file.

We make NO promises of backwards compatibility. This method may change or disappear at any time.

On input, this object is distributed over the Map returned by getMap() (the "original Map," with its communicator, the "original communicator"). The input newMap of this method must be the same as the result of calling getMap()->removeEmptyProcesses(). On processes in the original communicator which contain zero entries ("excluded processes," as opposed to "included processes"), the input newMap must be Teuchos::null (which is what getMap()->removeEmptyProcesses() returns anyway).

On included processes, reassign this object's Map (that would be returned by getMap()) to the input newMap, and do any work that needs to be done to restore correct semantics. On excluded processes, free any data that needs freeing, and do any other work that needs to be done to restore correct semantics.

This method has collective semantics over the original communicator. On exit, the only method of this object which is safe to call on excluded processes is the destructor. This implies that subclasses' destructors must not contain communication operations.

Returns

The object's new Map. Its communicator is a new communicator, distinct from the old Map's communicator, which contains a subset of the processes in the old communicator.

Note

The name differs from Map's method removeEmptyProcesses(), in order to emphasize that the operation on DistObject happens in place, modifying the input, whereas the operation removeEmptyProcess() on Map does not modify the input.

To implementers of DistObject subclasses: The default implementation of this class throws std::logic_error.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::setCopyOrView ( const Teuchos::DataAccess  copyOrView )

inlineinherited

Set whether this has copy (copyOrView = Teuchos::Copy) or view (copyOrView = Teuchos::View) semantics.

Warning

The Kokkos refactor version of MultiVector only implements view semantics. If you attempt to call this method with copyOrView == Teuchos::Copy, it will throw std::invalid_argument.

This method is only for expert use. It may change or disappear at any time.

Definition at line 2171 of file Tpetra_MultiVector_decl.hpp.

Teuchos::DataAccess Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getCopyOrView ( ) const

inlineinherited

Get whether this has copy (copyOrView = Teuchos::Copy) or view (copyOrView = Teuchos::View) semantics.

Warning

This method is only for expert use. It may change or disappear at any time.

Definition at line 2188 of file Tpetra_MultiVector_decl.hpp.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::assign ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  src )

inherited

Copy the contents of src into *this (deep copy).

Parameters

src	[in] Source MultiVector (input of the deep copy).

Precondition

! src.getMap ().is_null () && ! this->getMap ().is_null ()

src.getMap ()->isCompatible (* (this->getMap ())

Postcondition

Any outstanding views of src or *this remain valid.

Note

To implementers: The postcondition implies that the implementation must not reallocate any memory of *this, or otherwise change its dimensions. This is not an assignment operator; it does not change anything in *this other than the contents of storage.

Teuchos::RCP<MultiVector<T, LocalOrdinal, GlobalOrdinal, Node> > Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::convert ( ) const

inherited

Return another MultiVector with the same entries, but converted to a different Scalar type T.

bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::isSameSize ( const MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  vec ) const

inherited

Parameters

src	[in] MultiVector

Precondition

! vec.getMap ().is_null () && ! this->getMap ().is_null ()

vec.getMap ()->isCompatible (* (this->getMap ())

Postcondition

Any outstanding views of src or *this remain valid.

std::string Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::descriptionImpl ( const std::string &  className ) const

protectedinherited

Implementation of description() for this class, and its subclass Vector.

Parameters

className

[in] Name of the class calling this method: Either "Tpetra::MultiVector" or "Tpetra::Vector" (no quotes in the string, in either case).

std::string Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::localDescribeToString ( const Teuchos::EVerbosityLevel  vl ) const

protectedinherited

Print the calling process' verbose describe() information to the returned string.

This is an implementation detail of describe().

Parameters

vl	[in] Verbosity level with which to print.

void Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::describeImpl ( Teuchos::FancyOStream &  out, const std::string &  className, const Teuchos::EVerbosityLevel  verbLevel = Teuchos::Describable::verbLevel_default  ) const

protectedinherited

Implementation of describe() for this class, and its subclass Vector.

Parameters

out	[out] Output stream to which to write. Only Process 0 in this object's communicator may write to the output stream.
className	[in] Name of the class calling this method.
verbLevel	[in] Verbosity level. This also controls whether this method does any communication. At verbosity levels higher (greater) than Teuchos::VERB_LOW, this method behaves as a collective over the object's communicator.

Teuchos::ArrayRCP<T> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getSubArrayRCP ( Teuchos::ArrayRCP< T >  arr, size_t  j  ) const

protectedinherited

Persisting view of j-th column in the given ArrayRCP.

This method considers isConstantStride(). The ArrayRCP may correspond either to a compute buffer or a host view.

size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getOrigNumLocalRows ( ) const

protectedinherited

"Original" number of rows in the (local) data.

size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::getOrigNumLocalCols ( ) const

protectedinherited

"Original" number of columns in the (local) data.

virtual bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::checkSizes ( const SrcDistObject &  sourceObj )

overrideprotectedvirtualinherited

Whether data redistribution between sourceObj and this object is legal.

This method is called in DistObject::doTransfer() to check whether data redistribution between the two objects is legal.

Implements Tpetra::DistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node >.

virtual size_t Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::constantNumberOfPackets ( ) const

overrideprotectedvirtualinherited

Number of packets to send per LID.

Reimplemented from Tpetra::DistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node >.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::copyAndPermute ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const size_t  numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  permuteFromLIDs, const CombineMode  CM  )

protectedvirtualinherited

Perform copies and permutations that are local to the calling (MPI) process.

Subclasses must reimplement this function. Its default implementation does nothing. Note that the <t>target object of the Export or Import, namely *this, packs the source object's data.

Precondition

permuteToLIDs and permuteFromLIDs are sync'd to both host and device. That is, permuteToLIDs.need_sync_host(), permuteToLIDs.need_sync_device(), permuteFromLIDs.need_sync_host(), and permuteFromLIDs.need_sync_device() are all false.

Parameters

source	[in] On entry, the source object of the Export or Import operation.
numSameIDs	[in] The number of elements that are the same on the source and target objects. These elements live on the same process in both the source and target objects.
permuteToLIDs	[in] List of the elements that are permuted. They are listed by their local index (LID) in the destination object.
permuteFromLIDs	[in] List of the elements that are permuted. They are listed by their local index (LID) in the source object.
CM	[in] CombineMode to be used during copyAndPermute; may or may not be used by the particular object being called; behavior with respect to CombineMode may differ by object.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::copyAndPermute ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const size_t  numSameIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  permuteToLIDs, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  permuteFromLIDs, const CombineMode  CM, const execution_space &  space  )

protectedvirtualinherited

Same as copyAndPermute, but do operations in space.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::packAndPrepare ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  exportLIDs, Kokkos::DualView< packet_type *, buffer_device_type > &  exports, Kokkos::DualView< size_t *, buffer_device_type >  numPacketsPerLID, size_t &  constantNumPackets  )

protectedvirtualinherited

Pack data and metadata for communication (sends).

Subclasses must reimplement this function. Its default implementation does nothing. Note that the <t>target object of the Export or Import, namely *this, packs the source object's data.

Precondition

exportLIDs is sync'd to both host and device. That is, exportLIDs.need_sync_host () and exportLIDs.need_sync_device() are both false.

Parameters

source	[in] Source object for the redistribution.
exportLIDs	[in] List of the entries (as local IDs in the source object) that Tpetra will send to other processes.
exports	[out] On exit, the packed data to send. Implementations must reallocate this as needed (prefer reusing the existing allocation if possible), and may modify and/or sync this wherever they like.
numPacketsPerLID	[out] On exit, the implementation of this method must do one of two things: either set numPacketsPerLID[i] to the number of packets to be packed for exportLIDs[i] and set constantNumPackets to zero, or set constantNumPackets to a nonzero value. If the latter, the implementation must not modify the entries of numPacketsPerLID. If the former, the implementation may sync numPacketsPerLID this wherever it likes, either to host or to device. The allocation belongs to DistObject, not to subclasses; don't be tempted to change this to pass by reference.
constantNumPackets	[out] On exit, 0 if the number of packets per LID could differ, else (if nonzero) the number of packets per LID (which must be constant).

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::packAndPrepare ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  exportLIDs, Kokkos::DualView< packet_type *, buffer_device_type > &  exports, Kokkos::DualView< size_t *, buffer_device_type >  numPacketsPerLID, size_t &  constantNumPackets, const execution_space &  space  )

protectedvirtualinherited

Same as packAndPrepare, but in an execution space instance.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::unpackAndCombine ( const Kokkos::DualView< const local_ordinal_type *, buffer_device_type > &  importLIDs, Kokkos::DualView< packet_type *, buffer_device_type >  imports, Kokkos::DualView< size_t *, buffer_device_type >  numPacketsPerLID, const size_t  constantNumPackets, const CombineMode  combineMode  )

protectedvirtualinherited

Perform any unpacking and combining after communication.

Subclasses must reimplement this function. Its default implementation does nothing. Note that the <t>target object of the Export or Import, namely *this, unpacks the received data into itself, possibly modifying its entries.

Precondition

importLIDs is sync'd to both host and device. That is, importLIDs.need_sync_host () and importLIDs.need_sync_device() are both false.

Parameters

importLIDs	[in] List of the entries (as LIDs in the destination object) we received from other processes.
imports	[in/out] On input: Buffer of received data to unpack. DistObject promises nothing about where this is sync'd. Implementations may sync this wherever they like, either to host or to device. The allocation belongs to DistObject, not to subclasses; don't be tempted to change this to pass by reference.
numPacketsPerLID	[in/out] On input: If constantNumPackets is zero, then numPacketsPerLID[i] contains the number of packets imported for importLIDs[i]. DistObject promises nothing about where this is sync'd. Implementations may sync this wherever they like, either to host or to device. The allocation belongs to DistObject, not to subclasses; don't be tempted to change this to pass by reference.
constantNumPackets	[in] If nonzero, then the number of packets per LID is the same for all entries ("constant") and constantNumPackets is that number. If zero, then numPacketsPerLID[i] is the number of packets to unpack for LID importLIDs[i].
combineMode	[in] The CombineMode to use when combining the imported entries with existing entries.

virtual bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::reallocImportsIfNeeded ( const size_t  newSize, const bool  verbose, const std::string *  prefix, const bool  remoteLIDsContiguous = false, const CombineMode  CM = INSERT  )

overrideprotectedvirtualinherited

Reallocate imports_ if needed.

This unfortunately must be declared protected, for the same reason that imports_ is declared protected.

Parameters

newSize	[in] New size of imports_.
verbose	[in] Whether to print verbose debugging output to stderr on every (MPI) process in the communicator.
prefix	[in] If verbose is true, then this is a nonnull prefix to print at the beginning of each line of verbose debugging output. Otherwise, not used.

Returns

Whether we actually reallocated.

We don't need a "reallocExportsIfNeeded" method, because exports_ always gets passed into packAndPrepare() by nonconst reference. Thus, that method can resize the DualView without needing to call other DistObject methods.

Reimplemented from Tpetra::DistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node >.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::doImport ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Import< LocalOrdinal, GlobalOrdinal, Node > &  importer, const CombineMode  CM, const bool  restrictedMode = false  )

inherited

Import data into this object using an Import object ("forward mode").

The input DistObject is always the source of the data redistribution operation, and the *this object is always the target.

If you don't know the difference between forward and reverse mode, then you probably want forward mode. Use this method with your precomputed Import object if you want to do an Import, else use doExport() with a precomputed Export object.

"Restricted Mode" does two things:

1. Skips copyAndPermute
2. Allows the "target" Map of the transfer to be a subset of the Map of *this, in a "locallyFitted" sense.

This cannot be used if (2) is not true, OR there are permutes. The "source" maps still need to match.

Parameters

source	[in] The "source" object for redistribution.
importer	[in] Precomputed data redistribution plan. Its source Map must be the same as the input DistObject's Map, and its target Map must be the same as this->getMap().
CM	[in] How to combine incoming data with the same global index.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::doImport ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Export< LocalOrdinal, GlobalOrdinal, Node > &  exporter, const CombineMode  CM, const bool  restrictedMode = false  )

inherited

Import data into this object using an Export object ("reverse mode").

The input DistObject is always the source of the data redistribution operation, and the *this object is always the target.

If you don't know the difference between forward and reverse mode, then you probably want forward mode. Use the version of doImport() that takes a precomputed Import object in that case.

"Restricted Mode" does two things:

1. Skips copyAndPermute
2. Allows the "target" Map of the transfer to be a subset of the Map of *this, in a "locallyFitted" sense.

This cannot be used if (2) is not true, OR there are permutes. The "source" maps still need to match.

Parameters

source	[in] The "source" object for redistribution.
exporter	[in] Precomputed data redistribution plan. Its target Map must be the same as the input DistObject's Map, and its source Map must be the same as this->getMap(). (Note the difference from forward mode.)
CM	[in] How to combine incoming data with the same global index.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::doExport ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Export< LocalOrdinal, GlobalOrdinal, Node > &  exporter, const CombineMode  CM, const bool  restrictedMode = false  )

inherited

Export data into this object using an Export object ("forward mode").

The input DistObject is always the source of the data redistribution operation, and the *this object is always the target.

If you don't know the difference between forward and reverse mode, then you probably want forward mode. Use this method with your precomputed Export object if you want to do an Export, else use doImport() with a precomputed Import object.

"Restricted Mode" does two things:

1. Skips copyAndPermute
2. Allows the "target" Map of the transfer to be a subset of the Map of *this, in a "locallyFitted" sense.

This cannot be used if (2) is not true, OR there are permutes. The "source" maps still need to match.

Parameters

source	[in] The "source" object for redistribution.
exporter	[in] Precomputed data redistribution plan. Its source Map must be the same as the input DistObject's Map, and its target Map must be the same as this->getMap().
CM	[in] How to combine incoming data with the same global index.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::doExport ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  source, const Import< LocalOrdinal, GlobalOrdinal, Node > &  importer, const CombineMode  CM, const bool  restrictedMode = false  )

inherited

Export data into this object using an Import object ("reverse mode").

The input DistObject is always the source of the data redistribution operation, and the *this object is always the target.

If you don't know the difference between forward and reverse mode, then you probably want forward mode. Use the version of doExport() that takes a precomputed Export object in that case.

"Restricted Mode" does two things:

1. Skips copyAndPermute
2. Allows the "target" Map of the transfer to be a subset of the Map of *this, in a "locallyFitted" sense.

This cannot be used if (2) is not true, OR there are permutes. The "source" maps still need to match.

Parameters

source	[in] The "source" object for redistribution.
importer	[in] Precomputed data redistribution plan. Its target Map must be the same as the input DistObject's Map, and its source Map must be the same as this->getMap(). (Note the difference from forward mode.)
CM	[in] How to combine incoming data with the same global index.

bool Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::transferArrived ( ) const

inherited

Whether the data from an import/export operation has arrived, and is ready for the unpack and combine step.

bool Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::isDistributed ( ) const

inherited

Whether this is a globally distributed object.

For a definition of "globally distributed" (and its opposite, "locally replicated"), see the documentation of Map's isDistributed() method.

virtual Teuchos::RCP<const map_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::getMap ( ) const

inlinevirtualinherited

The Map describing the parallel distribution of this object.

Note that some Tpetra objects might be distributed using multiple Map objects. For example, CrsMatrix has both a row Map and a column Map. It is up to the subclass to decide which Map to use when invoking the DistObject constructor.

Definition at line 589 of file Tpetra_DistObject_decl.hpp.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::print ( std::ostream &  os ) const

inherited

Print this object to the given output stream.

We generally assume that all MPI processes can print to the given stream.

virtual void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::doTransfer ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  src, const ::Tpetra::Details::Transfer< local_ordinal_type, global_ordinal_type, node_type > &  transfer, const char  modeString[], const ReverseOption  revOp, const CombineMode  CM, const bool  restrictedMode  )

protectedvirtualinherited

Redistribute data across (MPI) processes.

Parameters

src	[in] The source object, to redistribute into the target object, which is *this object.
transfer	[in] The Export or Import object representing the communication pattern. (Details::Transfer is the common base class of these two objects.)
modeString	[in] Human-readable string, for verbose debugging output and error output, explaining what function called this method. Example: "doImport (forward)", "doExport (reverse)".
revOp	[in] Whether to do a forward or reverse mode redistribution.
CM	[in] The combine mode that describes how to combine values that map to the same global ID on the same process.

virtual bool Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::reallocArraysForNumPacketsPerLid ( const size_t  numExportLIDs, const size_t  numImportLIDs  )

protectedvirtualinherited

Reallocate numExportPacketsPerLID_ and/or numImportPacketsPerLID_, if necessary.

Parameters

numExportLIDs	[in] Number of entries in the exportLIDs input array argument of doTransfer().
numImportLIDs	[in] Number of entries in the remoteLIDs input array argument of doTransfer().

Returns

Whether we actually reallocated either of the arrays.

Warning

This is an implementation detail of doTransferNew(). This needs to be protected, but that doesn't mean users should call this method.

void Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::beginTransfer ( const SrcDistObject< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  src, const ::Tpetra::Details::Transfer< local_ordinal_type, global_ordinal_type, node_type > &  transfer, const char  modeString[], const ReverseOption  revOp, const CombineMode  CM, const bool  restrictedMode  )

protectedinherited

Implementation detail of doTransfer.

LID DualViews come from the Transfer object given to doTransfer. They are always sync'd on both host and device. Users must never attempt to modify or sync them.

Friends And Related Function Documentation

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Teuchos::RCP< MultiVector< Scalar, LocalOrdinal, GlobalOrdinal, Node > > createMultiVector ( const Teuchos::RCP< const Map< LocalOrdinal, GlobalOrdinal, Node > > &  map, const size_t  numVectors  )

related

Nonmember MultiVector "constructor": Create a MultiVector from a given Map.

Parameters

map	[in] Map describing the distribution of rows of the resulting MultiVector.
numVectors	[in] Number of columns of the resulting MultiVector.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > createCopy ( const Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > &  src )

related

Return a deep copy of the given Vector.

template<class Scalar , class LocalOrdinal , class GlobalOrdinal , class Node >

Teuchos::RCP< Vector< Scalar, LocalOrdinal, GlobalOrdinal, Node > > createVector ( const Teuchos::RCP< const Map< LocalOrdinal, GlobalOrdinal, Node > > &  map )

related

Nonmember Vector "constructor": Create a Vector from a given Map.

Parameters

map	[in] Map describing the distribution of rows of the resulting Vector.

Definition at line 428 of file Tpetra_Vector_decl.hpp.

Member Data Documentation

const bool Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::useAtomicUpdatesByDefault

staticprotectedinherited

Whether sumIntoLocalValue and sumIntoGlobalValue should use atomic updates by default.

Warning

This is an implementation detail.

Definition at line 844 of file Tpetra_MultiVector_decl.hpp.

wrapped_dual_view_type Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::view_

mutableprotectedinherited

The Kokkos::DualView containing the MultiVector's data.

This has to be declared mutable, so that get1dView() can retain its current const marking, even though it has always implied a device->host synchronization. Lesson to the reader: Use const sparingly!

Definition at line 2244 of file Tpetra_MultiVector_decl.hpp.

Teuchos::Array<size_t> Tpetra::MultiVector< Scalar , LocalOrdinal , GlobalOrdinal , Node >::whichVectors_

protectedinherited

Indices of columns this multivector is viewing.

If this array has nonzero size, then this multivector is a view of another multivector (the "original" multivector). In that case, whichVectors_ contains the indices of the columns of the original multivector. Furthermore, isConstantStride() returns false in this case.

If this array has zero size, then this multivector is not a view of any other multivector. Furthermore, the stride between columns of this multivector is a constant: thus, isConstantStride() returns true.

Definition at line 2258 of file Tpetra_MultiVector_decl.hpp.

Teuchos::RCP<const map_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::map_

protectedinherited

The Map over which this object is distributed.

Definition at line 998 of file Tpetra_DistObject_decl.hpp.

Kokkos::DualView<packet_type*, buffer_device_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::imports_

protectedinherited

Buffer into which packed data are imported (received from other processes).

Unfortunately, I had to declare these protected, because CrsMatrix uses them at one point. Please, nobody else use them.

Definition at line 1011 of file Tpetra_DistObject_decl.hpp.

Kokkos::DualView<size_t*, buffer_device_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::numImportPacketsPerLID_

protectedinherited

Number of packets to receive for each receive operation.

This array is used in Distributor::doPosts() (and doReversePosts()) when starting the ireceive operation.

This may be ignored in doTransfer() if constantNumPackets is nonzero, indicating a constant number of packets per LID. (For example, MultiVector sets the constantNumPackets output argument of packAndPrepare() to the number of columns in the multivector.)

Unfortunately, I had to declare this protected, because CrsMatrix uses it at one point. Please, nobody else use it.

Definition at line 1051 of file Tpetra_DistObject_decl.hpp.

Kokkos::DualView<packet_type*, buffer_device_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::exports_

protectedinherited

Buffer from which packed data are exported (sent to other processes).

Unfortunately, I had to declare this protected, because CrsMatrix uses it at one point. Please, nobody else use it.

Definition at line 1058 of file Tpetra_DistObject_decl.hpp.

Kokkos::DualView<size_t*, buffer_device_type> Tpetra::DistObject< Scalar , LocalOrdinal, GlobalOrdinal, Node >::numExportPacketsPerLID_

protectedinherited

Number of packets to send for each send operation.

This array is used in Distributor::doPosts() (and doReversePosts()) for preparing for the send operation.

This may be ignored in doTransfer() if constantNumPackets is nonzero, indicating a constant number of packets per LID. (For example, MultiVector sets the constantNumPackets output argument of packAndPrepare() to the number of columns in the multivector.)

Unfortunately, I had to declare this protected, because CrsMatrix uses them at one point. Please, nobody else use it.

Definition at line 1073 of file Tpetra_DistObject_decl.hpp.

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The documentation for this class was generated from the following files:

• Tpetra_Vector_decl.hpp
• Tpetra_MultiVector_decl.hpp
• Tpetra_Vector_def.hpp