SVecDVecMultExpr.h
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1 //=================================================================================================
33 //=================================================================================================
34 
35 #ifndef _BLAZE_MATH_EXPRESSIONS_SVECDVECMULTEXPR_H_
36 #define _BLAZE_MATH_EXPRESSIONS_SVECDVECMULTEXPR_H_
37 
38 
39 //*************************************************************************************************
40 // Includes
41 //*************************************************************************************************
42 
43 #include <iterator>
53 #include <blaze/math/shims/Reset.h>
63 #include <blaze/util/Assert.h>
65 #include <blaze/util/EnableIf.h>
66 #include <blaze/util/Exception.h>
68 #include <blaze/util/mpl/Max.h>
69 #include <blaze/util/SelectType.h>
70 #include <blaze/util/Types.h>
72 
73 
74 namespace blaze {
75 
76 //=================================================================================================
77 //
78 // CLASS SVECDVECMULTEXPR
79 //
80 //=================================================================================================
81 
82 //*************************************************************************************************
89 template< typename VT1 // Type of the left-hand side sparse vector
90  , typename VT2 // Type of the right-hand side dense vector
91  , bool TF > // Transpose flag
92 class SVecDVecMultExpr : public SparseVector< SVecDVecMultExpr<VT1,VT2,TF>, TF >
93  , private VecVecMultExpr
94  , private Computation
95 {
96  private:
97  //**Type definitions****************************************************************************
98  typedef typename VT1::ResultType RT1;
99  typedef typename VT2::ResultType RT2;
100  typedef typename VT1::ReturnType RN1;
101  typedef typename VT2::ReturnType RN2;
102  typedef typename VT1::CompositeType CT1;
103  typedef typename VT2::CompositeType CT2;
104  typedef typename VT1::TransposeType TT1;
105  typedef typename VT2::TransposeType TT2;
106  //**********************************************************************************************
107 
108  //**Return type evaluation**********************************************************************
110 
115  enum { returnExpr = !IsTemporary<RN1>::value && !IsTemporary<RN2>::value };
116 
119  //**********************************************************************************************
120 
121  //**Evaluation strategy*************************************************************************
123 
130 
132  template< typename VT >
134  struct UseAssign {
135  enum { value = useAssign };
136  };
138  //**********************************************************************************************
139 
140  public:
141  //**Type definitions****************************************************************************
146 
149 
152 
154  typedef typename SelectType< IsExpression<VT1>::value, const VT1, const VT1& >::Type LeftOperand;
155 
157  typedef typename SelectType< IsExpression<VT2>::value, const VT2, const VT2& >::Type RightOperand;
158  //**********************************************************************************************
159 
160  //**Compilation flags***************************************************************************
162  enum { smpAssignable = 0 };
163  //**********************************************************************************************
164 
165  //**ConstIterator class definition**************************************************************
169  {
170  public:
171  //**Type definitions*************************************************************************
174 
177 
178  typedef std::forward_iterator_tag IteratorCategory;
179  typedef ElementType ValueType;
180  typedef ValueType* PointerType;
181  typedef ValueType& ReferenceType;
183 
184  // STL iterator requirements
185  typedef IteratorCategory iterator_category;
186  typedef ValueType value_type;
187  typedef PointerType pointer;
188  typedef ReferenceType reference;
189  typedef DifferenceType difference_type;
190  //*******************************************************************************************
191 
192  //**Constructor******************************************************************************
195  inline ConstIterator( IteratorType it, RightOperand vec )
196  : it_ ( it ) // Iterator over the elements of the left-hand side sparse vector expression
197  , vec_( vec ) // Right-hand side dense vector expression
198  {}
199  //*******************************************************************************************
200 
201  //**Prefix increment operator****************************************************************
207  ++it_;
208  return *this;
209  }
210  //*******************************************************************************************
211 
212  //**Element access operator******************************************************************
217  inline const Element operator*() const {
218  return Element( it_->value() * vec_[it_->index()], it_->index() );
219  }
220  //*******************************************************************************************
221 
222  //**Element access operator******************************************************************
227  inline const ConstIterator* operator->() const {
228  return this;
229  }
230  //*******************************************************************************************
231 
232  //**Value function***************************************************************************
237  inline ReturnType value() const {
238  return it_->value() * vec_[it_->index()];
239  }
240  //*******************************************************************************************
241 
242  //**Index function***************************************************************************
247  inline size_t index() const {
248  return it_->index();
249  }
250  //*******************************************************************************************
251 
252  //**Equality operator************************************************************************
258  inline bool operator==( const ConstIterator& rhs ) const {
259  return it_ == rhs.it_;
260  }
261  //*******************************************************************************************
262 
263  //**Inequality operator**********************************************************************
269  inline bool operator!=( const ConstIterator& rhs ) const {
270  return it_ != rhs.it_;
271  }
272  //*******************************************************************************************
273 
274  //**Subtraction operator*********************************************************************
280  inline DifferenceType operator-( const ConstIterator& rhs ) const {
281  return it_ - rhs.it_;
282  }
283  //*******************************************************************************************
284 
285  private:
286  //**Member variables*************************************************************************
287  IteratorType it_;
288  RightOperand vec_;
289  //*******************************************************************************************
290  };
291  //**********************************************************************************************
292 
293  //**Constructor*********************************************************************************
299  explicit inline SVecDVecMultExpr( const VT1& lhs, const VT2& rhs )
300  : lhs_( lhs ) // Left-hand side sparse vector of the multiplication expression
301  , rhs_( rhs ) // Right-hand side dense vector of the multiplication expression
302  {
303  BLAZE_INTERNAL_ASSERT( lhs.size() == rhs.size(), "Invalid vector sizes" );
304  }
305  //**********************************************************************************************
306 
307  //**Subscript operator**************************************************************************
313  inline ReturnType operator[]( size_t index ) const {
314  BLAZE_INTERNAL_ASSERT( index < lhs_.size(), "Invalid vector access index" );
315  return lhs_[index] * rhs_[index];
316  }
317  //**********************************************************************************************
318 
319  //**At function*********************************************************************************
326  inline ReturnType at( size_t index ) const {
327  if( index >= lhs_.size() ) {
328  BLAZE_THROW_OUT_OF_RANGE( "Invalid vector access index" );
329  }
330  return (*this)[index];
331  }
332  //**********************************************************************************************
333 
334  //**Begin function******************************************************************************
339  inline ConstIterator begin() const {
340  return ConstIterator( lhs_.begin(), rhs_ );
341  }
342  //**********************************************************************************************
343 
344  //**End function********************************************************************************
349  inline ConstIterator end() const {
350  return ConstIterator( lhs_.end(), rhs_ );
351  }
352  //**********************************************************************************************
353 
354  //**Size function*******************************************************************************
359  inline size_t size() const {
360  return rhs_.size();
361  }
362  //**********************************************************************************************
363 
364  //**NonZeros function***************************************************************************
369  inline size_t nonZeros() const {
370  return lhs_.nonZeros();
371  }
372  //**********************************************************************************************
373 
374  //**Find function*******************************************************************************
380  inline ConstIterator find( size_t index ) const {
382  return ConstIterator( lhs_.find( index ), rhs_ );
383  }
384  //**********************************************************************************************
385 
386  //**LowerBound function*************************************************************************
392  inline ConstIterator lowerBound( size_t index ) const {
394  return ConstIterator( lhs_.lowerBound( index ), rhs_ );
395  }
396  //**********************************************************************************************
397 
398  //**UpperBound function*************************************************************************
404  inline ConstIterator upperBound( size_t index ) const {
406  return ConstIterator( lhs_.upperBound( index ), rhs_ );
407  }
408  //**********************************************************************************************
409 
410  //**Left operand access*************************************************************************
415  inline LeftOperand leftOperand() const {
416  return lhs_;
417  }
418  //**********************************************************************************************
419 
420  //**Right operand access************************************************************************
425  inline RightOperand rightOperand() const {
426  return rhs_;
427  }
428  //**********************************************************************************************
429 
430  //**********************************************************************************************
436  template< typename T >
437  inline bool canAlias( const T* alias ) const {
438  return ( lhs_.canAlias( alias ) ) || ( rhs_.canAlias( alias ) );
439  }
440  //**********************************************************************************************
441 
442  //**********************************************************************************************
448  template< typename T >
449  inline bool isAliased( const T* alias ) const {
450  return ( lhs_.isAliased( alias ) ) || ( rhs_.isAliased( alias ) );
451  }
452  //**********************************************************************************************
453 
454  private:
455  //**Member variables****************************************************************************
456  LeftOperand lhs_;
457  RightOperand rhs_;
458  //**********************************************************************************************
459 
460  //**Assignment to dense vectors*****************************************************************
474  template< typename VT > // Type of the target dense vector
475  friend inline typename EnableIf< UseAssign<VT> >::Type
476  assign( DenseVector<VT,TF>& lhs, const SVecDVecMultExpr& rhs )
477  {
479 
480  BLAZE_INTERNAL_ASSERT( (~lhs).size() == rhs.size(), "Invalid vector sizes" );
481 
483 
484  CT1 x( serial( rhs.lhs_ ) ); // Evaluation of the left-hand side sparse vector operand
485  CT2 y( serial( rhs.rhs_ ) ); // Evaluation of the right-hand side dense vector operand
486 
487  BLAZE_INTERNAL_ASSERT( x.size() == rhs.lhs_.size(), "Invalid vector size" );
488  BLAZE_INTERNAL_ASSERT( y.size() == rhs.rhs_.size(), "Invalid vector size" );
489  BLAZE_INTERNAL_ASSERT( x.size() == (~lhs).size() , "Invalid vector size" );
490 
491  for( ConstIterator element=x.begin(); element!=x.end(); ++element )
492  (~lhs)[element->index()] = element->value() * y[element->index()];
493  }
495  //**********************************************************************************************
496 
497  //**Assignment to sparse vectors****************************************************************
511  template< typename VT > // Type of the target sparse vector
512  friend inline typename EnableIf< UseAssign<VT> >::Type
513  assign( SparseVector<VT,TF>& lhs, const SVecDVecMultExpr& rhs )
514  {
516 
517  BLAZE_INTERNAL_ASSERT( (~lhs).size() == rhs.size(), "Invalid vector sizes" );
518 
520 
521  CT1 x( serial( rhs.lhs_ ) ); // Evaluation of the left-hand side sparse vector operand
522  CT2 y( serial( rhs.rhs_ ) ); // Evaluation of the right-hand side dense vector operand
523 
524  BLAZE_INTERNAL_ASSERT( x.size() == rhs.lhs_.size(), "Invalid vector size" );
525  BLAZE_INTERNAL_ASSERT( y.size() == rhs.rhs_.size(), "Invalid vector size" );
526  BLAZE_INTERNAL_ASSERT( x.size() == (~lhs).size() , "Invalid vector size" );
527 
528  for( ConstIterator element=x.begin(); element!=x.end(); ++element )
529  (~lhs).append( element->index(), element->value() * y[element->index()] );
530  }
532  //**********************************************************************************************
533 
534  //**Addition assignment to dense vectors********************************************************
548  template< typename VT > // Type of the target dense vector
549  friend inline typename EnableIf< UseAssign<VT> >::Type
550  addAssign( DenseVector<VT,TF>& lhs, const SVecDVecMultExpr& rhs )
551  {
553 
554  BLAZE_INTERNAL_ASSERT( (~lhs).size() == rhs.size(), "Invalid vector sizes" );
555 
557 
558  CT1 x( serial( rhs.lhs_ ) ); // Evaluation of the left-hand side sparse vector operand
559  CT2 y( serial( rhs.rhs_ ) ); // Evaluation of the right-hand side dense vector operand
560 
561  BLAZE_INTERNAL_ASSERT( x.size() == rhs.lhs_.size(), "Invalid vector size" );
562  BLAZE_INTERNAL_ASSERT( y.size() == rhs.rhs_.size(), "Invalid vector size" );
563  BLAZE_INTERNAL_ASSERT( x.size() == (~lhs).size() , "Invalid vector size" );
564 
565  for( ConstIterator element=x.begin(); element!=x.end(); ++element )
566  (~lhs)[element->index()] += element->value() * y[element->index()];
567  }
569  //**********************************************************************************************
570 
571  //**Addition assignment to sparse vectors*******************************************************
572  // No special implementation for the addition assignment to sparse vectors.
573  //**********************************************************************************************
574 
575  //**Subtraction assignment to dense vectors*****************************************************
589  template< typename VT > // Type of the target dense vector
590  friend inline typename EnableIf< UseAssign<VT> >::Type
591  subAssign( DenseVector<VT,TF>& lhs, const SVecDVecMultExpr& rhs )
592  {
594 
595  BLAZE_INTERNAL_ASSERT( (~lhs).size() == rhs.size(), "Invalid vector sizes" );
596 
598 
599  CT1 x( serial( rhs.lhs_ ) ); // Evaluation of the left-hand side sparse vector operand
600  CT2 y( serial( rhs.rhs_ ) ); // Evaluation of the right-hand side dense vector operand
601 
602  BLAZE_INTERNAL_ASSERT( x.size() == rhs.lhs_.size(), "Invalid vector size" );
603  BLAZE_INTERNAL_ASSERT( y.size() == rhs.rhs_.size(), "Invalid vector size" );
604  BLAZE_INTERNAL_ASSERT( x.size() == (~lhs).size() , "Invalid vector size" );
605 
606  for( ConstIterator element=x.begin(); element!=x.end(); ++element )
607  (~lhs)[element->index()] -= element->value() * y[element->index()];
608  }
610  //**********************************************************************************************
611 
612  //**Subtraction assignment to sparse vectors****************************************************
613  // No special implementation for the subtraction assignment to sparse vectors.
614  //**********************************************************************************************
615 
616  //**Multiplication assignment to dense vectors**************************************************
630  template< typename VT > // Type of the target dense vector
631  friend inline typename EnableIf< UseAssign<VT> >::Type
632  multAssign( DenseVector<VT,TF>& lhs, const SVecDVecMultExpr& rhs )
633  {
635 
636  BLAZE_INTERNAL_ASSERT( (~lhs).size() == rhs.size(), "Invalid vector sizes" );
637 
639 
640  CT1 x( serial( rhs.lhs_ ) ); // Evaluation of the left-hand side sparse vector operand
641  CT2 y( serial( rhs.rhs_ ) ); // Evaluation of the right-hand side dense vector operand
642 
643  BLAZE_INTERNAL_ASSERT( x.size() == rhs.lhs_.size(), "Invalid vector size" );
644  BLAZE_INTERNAL_ASSERT( y.size() == rhs.rhs_.size(), "Invalid vector size" );
645  BLAZE_INTERNAL_ASSERT( x.size() == (~lhs).size() , "Invalid vector size" );
646 
647  const ConstIterator end( x.end() );
648  ConstIterator begin( x.begin() );
649  size_t i( 0UL );
650 
651  for( ; begin!=end; ++begin ) {
652  const size_t index( begin->index() );
653  for( ; i<index; ++i )
654  reset( (~lhs)[i] );
655  (~lhs)[index] *= begin->value() * y[index];
656  ++i;
657  }
658 
659  for( ; i<rhs.size(); ++i )
660  reset( (~lhs)[i] );
661  }
663  //**********************************************************************************************
664 
665  //**Multiplication assignment to sparse vectors*************************************************
666  // No special implementation for the multiplication assignment to sparse vectors.
667  //**********************************************************************************************
668 
669  //**Compile time checks*************************************************************************
677  //**********************************************************************************************
678 };
679 //*************************************************************************************************
680 
681 
682 
683 
684 //=================================================================================================
685 //
686 // GLOBAL BINARY ARITHMETIC OPERATORS
687 //
688 //=================================================================================================
689 
690 //*************************************************************************************************
717 template< typename T1 // Type of the left-hand side sparse vector
718  , typename T2 // Type of the right-hand side dense vector
719  , bool TF > // Transpose flag
720 inline const SVecDVecMultExpr<T1,T2,TF>
722 {
724 
725  if( (~lhs).size() != (~rhs).size() ) {
726  BLAZE_THROW_INVALID_ARGUMENT( "Vector sizes do not match" );
727  }
728 
729  return SVecDVecMultExpr<T1,T2,TF>( ~lhs, ~rhs );
730 }
731 //*************************************************************************************************
732 
733 
734 
735 
736 //=================================================================================================
737 //
738 // SIZE SPECIALIZATIONS
739 //
740 //=================================================================================================
741 
742 //*************************************************************************************************
744 template< typename VT1, typename VT2, bool TF >
745 struct Size< SVecDVecMultExpr<VT1,VT2,TF> >
746  : public Max< Size<VT1>, Size<VT2> >
747 {};
749 //*************************************************************************************************
750 
751 
752 
753 
754 //=================================================================================================
755 //
756 // EXPRESSION TRAIT SPECIALIZATIONS
757 //
758 //=================================================================================================
759 
760 //*************************************************************************************************
762 template< typename VT1, typename VT2, bool TF, bool AF >
763 struct SubvectorExprTrait< SVecDVecMultExpr<VT1,VT2,TF>, AF >
764 {
765  public:
766  //**********************************************************************************************
767  typedef typename MultExprTrait< typename SubvectorExprTrait<const VT1,AF>::Type
768  , typename SubvectorExprTrait<const VT2,AF>::Type >::Type Type;
769  //**********************************************************************************************
770 };
772 //*************************************************************************************************
773 
774 } // namespace blaze
775 
776 #endif
#define BLAZE_THROW_INVALID_ARGUMENT(MESSAGE)
Macro for the emission of a std::invalid_argument exceptionThis macro encapsulates the default way of...
Definition: Exception.h:187
Pointer difference type of the Blaze library.
Header file for the Max class template.
ValueIndexPair< ElementType > Element
Element type of the sparse vector expression.
Definition: SVecDVecMultExpr.h:173
ValueType value_type
Type of the underlying pointers.
Definition: SVecDVecMultExpr.h:186
Compile time check whether the given type is a temporary vector or matrix type.This type trait class ...
Definition: IsTemporary.h:87
const DMatDMatMultExpr< T1, T2 > operator*(const DenseMatrix< T1, false > &lhs, const DenseMatrix< T2, false > &rhs)
Multiplication operator for the multiplication of two row-major dense matrices ( ).
Definition: DMatDMatMultExpr.h:7820
ConstIterator end() const
Returns an iterator just past the last non-zero element of the sparse vector.
Definition: SVecDVecMultExpr.h:349
Header file for basic type definitions.
RightOperand rightOperand() const
Returns the right-hand side dense vector operand.
Definition: SVecDVecMultExpr.h:425
Header file for the SparseVector base class.
size_t size() const
Returns the current size/dimension of the vector.
Definition: SVecDVecMultExpr.h:359
ConstIterator upperBound(size_t index) const
Returns an iterator to the first index greater then the given index.
Definition: SVecDVecMultExpr.h:404
ReturnType operator[](size_t index) const
Subscript operator for the direct access to the vector elements.
Definition: SVecDVecMultExpr.h:313
ReturnType at(size_t index) const
Checked access to the vector elements.
Definition: SVecDVecMultExpr.h:326
size_t nonZeros() const
Returns the number of non-zero elements in the sparse vector.
Definition: SVecDVecMultExpr.h:369
Efficient implementation of a compressed matrix.The CompressedMatrix class template is the represent...
Definition: CompressedMatrix.h:207
PointerType pointer
Pointer return type.
Definition: SVecDVecMultExpr.h:187
bool operator==(const ConstIterator &rhs) const
Equality comparison between two ConstIterator objects.
Definition: SVecDVecMultExpr.h:258
ReturnType value() const
Access to the current value of the sparse element.
Definition: SVecDVecMultExpr.h:237
void reset(const DiagonalProxy< MT > &proxy)
Resetting the represented element to the default initial values.
Definition: DiagonalProxy.h:507
RightOperand rhs_
Right-hand side dense vector of the multiplication expression.
Definition: SVecDVecMultExpr.h:457
const This & CompositeType
Data type for composite expression templates.
Definition: CompressedMatrix.h:2588
Type ElementType
Type of the sparse matrix elements.
Definition: CompressedMatrix.h:259
SVecDVecMultExpr(const VT1 &lhs, const VT2 &rhs)
Constructor for the SVecDVecMultExpr class.
Definition: SVecDVecMultExpr.h:299
ReferenceType reference
Reference return type.
Definition: SVecDVecMultExpr.h:188
const Element operator*() const
Direct access to the sparse vector element at the current iterator position.
Definition: SVecDVecMultExpr.h:217
const DMatSerialExpr< MT, SO > serial(const DenseMatrix< MT, SO > &dm)
Forces the serial evaluation of the given dense matrix expression dm.
Definition: DMatSerialExpr.h:721
Header file for the Computation base class.
Header file for the RequiresEvaluation type trait.
VT2::CompositeType CT2
Composite type of the right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:103
ResultType::ElementType ElementType
Resulting element type.
Definition: SVecDVecMultExpr.h:145
Constraint on the data type.
ConstIterator(IteratorType it, RightOperand vec)
Constructor for the ConstIterator class.
Definition: SVecDVecMultExpr.h:195
Header file for the MultExprTrait class template.
Compile time check to query the requirement to evaluate an expression.Via this type trait it is possi...
Definition: RequiresEvaluation.h:90
VT2::ResultType RT2
Result type of the right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:99
ValueType & ReferenceType
Reference return type.
Definition: SVecDVecMultExpr.h:181
Header file for the ValueIndexPair class.
ConstIterator lowerBound(size_t index) const
Returns an iterator to the first index not less then the given index.
Definition: SVecDVecMultExpr.h:392
Compile time type selection.The SelectType class template selects one of the two given types T1 and T...
Definition: SelectType.h:59
Header file for the IsTemporary type trait class.
SelectType< useAssign, const ResultType, const SVecDVecMultExpr & >::Type CompositeType
Data type for composite expression templates.
Definition: SVecDVecMultExpr.h:151
Header file for the multiplication trait.
Namespace of the Blaze C++ math library.
Definition: Blaze.h:57
DifferenceType difference_type
Difference between two iterators.
Definition: SVecDVecMultExpr.h:189
ResultType::TransposeType TransposeType
Transpose type for expression template evaluations.
Definition: SVecDVecMultExpr.h:144
ptrdiff_t DifferenceType
Difference between two iterators.
Definition: SVecDVecMultExpr.h:182
const Element * ConstIterator
Iterator over constant elements.
Definition: CompressedMatrix.h:2592
#define BLAZE_THROW_OUT_OF_RANGE(MESSAGE)
Macro for the emission of a std::out_of_range exceptionThis macro encapsulates the default way of Bla...
Definition: Exception.h:331
IteratorType it_
Iterator over the elements of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:287
Base class for N-dimensional dense vectors.The DenseVector class is a base class for all arbitrarily ...
Definition: DenseVector.h:70
#define BLAZE_CONSTRAINT_MUST_BE_SPARSE_VECTOR_TYPE(T)
Constraint on the data type.In case the given data type T is not a sparse, N-dimensional vector type...
Definition: SparseVector.h:79
std::forward_iterator_tag IteratorCategory
The iterator category.
Definition: SVecDVecMultExpr.h:178
Constraint on the data type.
bool canAlias(const T *alias) const
Returns whether the expression can alias with the given address alias.
Definition: SVecDVecMultExpr.h:437
SelectType< IsExpression< VT2 >::value, const VT2, const VT2 & >::Type RightOperand
Composite type of the right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:157
DifferenceType operator-(const ConstIterator &rhs) const
Calculating the number of elements between two expression iterators.
Definition: SVecDVecMultExpr.h:280
bool operator!=(const ConstIterator &rhs) const
Inequality comparison between two ConstIterator objects.
Definition: SVecDVecMultExpr.h:269
CompressedMatrix< Type, false > TransposeType
Transpose type for expression template evaluations.
Definition: CompressedMatrix.h:2585
Constraint on the data type.
Header file for the VecVecMultExpr base class.
ConstIterator find(size_t index) const
Searches for a specific vector element.
Definition: SVecDVecMultExpr.h:380
Constraint on the data type.
Header file for the SelectType class template.
Header file for all forward declarations for expression class templates.
Constraint on the data type.
VT2::TransposeType TT2
Transpose type of the right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:105
Iterator over the elements of the sparse vector-dense vector multiplication expression.
Definition: SVecDVecMultExpr.h:168
ConstIterator & operator++()
Pre-increment operator.
Definition: SVecDVecMultExpr.h:206
Header file for the EnableIf class template.
Header file for the serial shim.
const SelectType< returnExpr, ExprReturnType, ElementType >::Type ReturnType
Return type for expression template evaluations.
Definition: SVecDVecMultExpr.h:148
LeftOperand lhs_
Left-hand side sparse vector of the multiplication expression.
Definition: SVecDVecMultExpr.h:456
const Type & ReturnType
Return type for expression template evaluations.
Definition: CompressedMatrix.h:2587
Removal of reference modifiers.The RemoveCV type trait removes any reference modifiers from the given...
Definition: RemoveReference.h:69
VT1::CompositeType CT1
Composite type of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:102
Header file for run time assertion macros.
Base template for the MultTrait class.
Definition: MultTrait.h:138
Substitution Failure Is Not An Error (SFINAE) class.The EnableIf class template is an auxiliary tool ...
Definition: EnableIf.h:184
Header file for the reset shim.
ConstIterator begin() const
Returns an iterator to the first non-zero element of the sparse vector.
Definition: SVecDVecMultExpr.h:339
bool isAliased(const T *alias) const
Returns whether the expression is aliased with the given address alias.
Definition: SVecDVecMultExpr.h:449
size_t index() const
Access to the current index of the sparse element.
Definition: SVecDVecMultExpr.h:247
#define BLAZE_CONSTRAINT_MUST_NOT_REQUIRE_EVALUATION(T)
Constraint on the data type.In case the given data type T requires an intermediate evaluation within ...
Definition: RequiresEvaluation.h:118
Header file for the RemoveReference type trait.
SVecDVecMultExpr< VT1, VT2, TF > This
Type of this SVecDVecMultExpr instance.
Definition: SVecDVecMultExpr.h:142
RemoveReference< LeftOperand >::Type::ConstIterator IteratorType
Iterator type of the sparse vector expression.
Definition: SVecDVecMultExpr.h:176
#define BLAZE_CONSTRAINT_MUST_BE_DENSE_VECTOR_TYPE(T)
Constraint on the data type.In case the given data type T is not a dense, N-dimensional vector type...
Definition: DenseVector.h:79
Index-value-pair for sparse vectors and matrices.The ValueIndexPair class represents a single index-v...
Definition: ValueIndexPair.h:70
Constraint on the data type.
LeftOperand leftOperand() const
Returns the left-hand side sparse vector operand.
Definition: SVecDVecMultExpr.h:415
#define BLAZE_CONSTRAINT_MUST_FORM_VALID_VECVECMULTEXPR(T1, T2)
Constraint on the data type.In case the given data types T1 and T2 do not form a valid vector/vector ...
Definition: VecVecMultExpr.h:165
Base class for sparse vectors.The SparseVector class is a base class for all arbitrarily sized (N-dim...
Definition: Forward.h:118
#define BLAZE_FUNCTION_TRACE
Function trace macro.This macro can be used to reliably trace function calls. In case function tracin...
Definition: FunctionTrace.h:157
SelectType< IsExpression< VT1 >::value, const VT1, const VT1 & >::Type LeftOperand
Composite type of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:154
This ResultType
Result type for expression template evaluations.
Definition: CompressedMatrix.h:2583
MultExprTrait< RN1, RN2 >::Type ExprReturnType
Expression return type for the subscript operator.
Definition: SVecDVecMultExpr.h:118
ElementType ValueType
Type of the underlying pointers.
Definition: SVecDVecMultExpr.h:179
Header file for the SubvectorExprTrait class template.
const ConstIterator * operator->() const
Direct access to the sparse vector element at the current iterator position.
Definition: SVecDVecMultExpr.h:227
Header file for exception macros.
ValueType * PointerType
Pointer return type.
Definition: SVecDVecMultExpr.h:180
RightOperand vec_
Right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:288
IteratorCategory iterator_category
The iterator category.
Definition: SVecDVecMultExpr.h:185
VT1::ReturnType RN1
Return type of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:100
VT2::ReturnType RN2
Return type of the right-hand side dense vector expression.
Definition: SVecDVecMultExpr.h:101
VT1::TransposeType TT1
Transpose type of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:104
Header file for the Size type trait.
Evaluation of the resulting expression type of a multiplication.Via this type trait it is possible to...
Definition: MultExprTrait.h:137
#define BLAZE_CONSTRAINT_MUST_BE_VECTOR_WITH_TRANSPOSE_FLAG(T, TF)
Constraint on the data type.In case the given data type T is not a dense or sparse vector type and in...
Definition: TransposeFlag.h:81
MultTrait< RT1, RT2 >::Type ResultType
Result type for expression template evaluations.
Definition: SVecDVecMultExpr.h:143
#define BLAZE_INTERNAL_ASSERT(expr, msg)
Run time assertion macro for internal checks.In case of an invalid run time expression, the program execution is terminated. The BLAZE_INTERNAL_ASSERT macro can be disabled by setting the BLAZE_USER_ASSERTION flag to zero or by defining NDEBUG during the compilation.
Definition: Assert.h:101
Header file for the IsExpression type trait class.
VT1::ResultType RT1
Result type of the left-hand side sparse vector expression.
Definition: SVecDVecMultExpr.h:98
Header file for the FunctionTrace class.
Expression object for sparse vector-dense vector multiplications.The SVecDVecMultExpr class represent...
Definition: Forward.h:122