📄 matrix_sparse.hpp
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++ it_;
else
*this = (*this) ().find2 (rank_, i_, index2 () + 1, 1);
return *this;
}
BOOST_UBLAS_INLINE
const_iterator2 &operator -- () {
if (rank_ == 1 && layout_type::fast2 ())
-- it_;
else
*this = (*this) ().find2 (rank_, i_, index2 () - 1, -1);
return *this;
}
// Dereference
BOOST_UBLAS_INLINE
const_reference operator * () const {
BOOST_UBLAS_CHECK (index1 () < (*this) ().size1 (), bad_index ());
BOOST_UBLAS_CHECK (index2 () < (*this) ().size2 (), bad_index ());
if (rank_ == 1) {
return (*it_).second;
} else {
return (*this) () (i_, j_);
}
}
#ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
const_iterator1 begin () const {
const self_type &m = (*this) ();
return m.find1 (1, 0, index2 ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
const_iterator1 end () const {
const self_type &m = (*this) ();
return m.find1 (1, m.size1 (), index2 ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
const_reverse_iterator1 rbegin () const {
return const_reverse_iterator1 (end ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
const_reverse_iterator1 rend () const {
return const_reverse_iterator1 (begin ());
}
#endif
// Indices
BOOST_UBLAS_INLINE
size_type index1 () const {
if (rank_ == 1) {
const self_type &m = (*this) ();
BOOST_UBLAS_CHECK (layout_type::index1 ((*it_).first, m.size1 (), m.size2 ()) < (*this) ().size1 (), bad_index ());
return layout_type::index1 ((*it_).first, m.size1 (), m.size2 ());
} else {
return i_;
}
}
BOOST_UBLAS_INLINE
size_type index2 () const {
BOOST_UBLAS_CHECK (*this != (*this) ().find2 (0, i_, (*this) ().size2 ()), bad_index ());
if (rank_ == 1) {
const self_type &m = (*this) ();
BOOST_UBLAS_CHECK (layout_type::index2 ((*it_).first, m.size1 (), m.size2 ()) < (*this) ().size2 (), bad_index ());
return layout_type::index2 ((*it_).first, m.size1 (), m.size2 ());
} else {
return j_;
}
}
// Assignment
BOOST_UBLAS_INLINE
const_iterator2 &operator = (const const_iterator2 &it) {
container_const_reference<self_type>::assign (&it ());
rank_ = it.rank_;
i_ = it.i_;
j_ = it.j_;
it_ = it.it_;
return *this;
}
// Comparison
BOOST_UBLAS_INLINE
bool operator == (const const_iterator2 &it) const {
BOOST_UBLAS_CHECK (&(*this) () == &it (), external_logic ());
// BOOST_UBLAS_CHECK (rank_ == it.rank_, internal_logic ());
if (rank_ == 1 || it.rank_ == 1) {
return it_ == it.it_;
} else {
return i_ == it.i_ && j_ == it.j_;
}
}
private:
int rank_;
size_type i_;
size_type j_;
const_subiterator_type it_;
};
BOOST_UBLAS_INLINE
const_iterator2 begin2 () const {
return find2 (0, 0, 0);
}
BOOST_UBLAS_INLINE
const_iterator2 end2 () const {
return find2 (0, 0, size2_);
}
class iterator2:
public container_reference<mapped_matrix>,
public bidirectional_iterator_base<sparse_bidirectional_iterator_tag,
iterator2, value_type> {
public:
typedef typename mapped_matrix::value_type value_type;
typedef typename mapped_matrix::difference_type difference_type;
typedef typename mapped_matrix::true_reference reference;
typedef typename mapped_matrix::pointer pointer;
typedef iterator1 dual_iterator_type;
typedef reverse_iterator1 dual_reverse_iterator_type;
// Construction and destruction
BOOST_UBLAS_INLINE
iterator2 ():
container_reference<self_type> (), rank_ (), i_ (), j_ (), it_ () {}
BOOST_UBLAS_INLINE
iterator2 (self_type &m, int rank, size_type i, size_type j, const subiterator_type &it):
container_reference<self_type> (m), rank_ (rank), i_ (i), j_ (j), it_ (it) {}
// Arithmetic
BOOST_UBLAS_INLINE
iterator2 &operator ++ () {
if (rank_ == 1 && layout_type::fast2 ())
++ it_;
else
*this = (*this) ().find2 (rank_, i_, index2 () + 1, 1);
return *this;
}
BOOST_UBLAS_INLINE
iterator2 &operator -- () {
if (rank_ == 1 && layout_type::fast2 ())
-- it_;
else
*this = (*this) ().find2 (rank_, i_, index2 () - 1, -1);
return *this;
}
// Dereference
BOOST_UBLAS_INLINE
reference operator * () const {
BOOST_UBLAS_CHECK (index1 () < (*this) ().size1 (), bad_index ());
BOOST_UBLAS_CHECK (index2 () < (*this) ().size2 (), bad_index ());
if (rank_ == 1) {
return (*it_).second;
} else {
return (*this) ().at_element (i_, j_);
}
}
#ifndef BOOST_UBLAS_NO_NESTED_CLASS_RELATION
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
iterator1 begin () const {
self_type &m = (*this) ();
return m.find1 (1, 0, index2 ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
iterator1 end () const {
self_type &m = (*this) ();
return m.find1 (1, m.size1 (), index2 ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
reverse_iterator1 rbegin () const {
return reverse_iterator1 (end ());
}
BOOST_UBLAS_INLINE
#ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION
typename self_type::
#endif
reverse_iterator1 rend () const {
return reverse_iterator1 (begin ());
}
#endif
// Indices
BOOST_UBLAS_INLINE
size_type index1 () const {
if (rank_ == 1) {
const self_type &m = (*this) ();
BOOST_UBLAS_CHECK (layout_type::index1 ((*it_).first, m.size1 (), m.size2 ()) < (*this) ().size1 (), bad_index ());
return layout_type::index1 ((*it_).first, m.size1 (), m.size2 ());
} else {
return i_;
}
}
BOOST_UBLAS_INLINE
size_type index2 () const {
BOOST_UBLAS_CHECK (*this != (*this) ().find2 (0, i_, (*this) ().size2 ()), bad_index ());
if (rank_ == 1) {
const self_type &m = (*this) ();
BOOST_UBLAS_CHECK (layout_type::index2 ((*it_).first, m.size1 (), m.size2 ()) < (*this) ().size2 (), bad_index ());
return layout_type::index2 ((*it_).first, m.size1 (), m.size2 ());
} else {
return j_;
}
}
// Assignment
BOOST_UBLAS_INLINE
iterator2 &operator = (const iterator2 &it) {
container_reference<self_type>::assign (&it ());
rank_ = it.rank_;
i_ = it.i_;
j_ = it.j_;
it_ = it.it_;
return *this;
}
// Comparison
BOOST_UBLAS_INLINE
bool operator == (const iterator2 &it) const {
BOOST_UBLAS_CHECK (&(*this) () == &it (), external_logic ());
// BOOST_UBLAS_CHECK (rank_ == it.rank_, internal_logic ());
if (rank_ == 1 || it.rank_ == 1) {
return it_ == it.it_;
} else {
return i_ == it.i_ && j_ == it.j_;
}
}
private:
int rank_;
size_type i_;
size_type j_;
subiterator_type it_;
friend class const_iterator2;
};
BOOST_UBLAS_INLINE
iterator2 begin2 () {
return find2 (0, 0, 0);
}
BOOST_UBLAS_INLINE
iterator2 end2 () {
return find2 (0, 0, size2_);
}
// Reverse iterators
BOOST_UBLAS_INLINE
const_reverse_iterator1 rbegin1 () const {
return const_reverse_iterator1 (end1 ());
}
BOOST_UBLAS_INLINE
const_reverse_iterator1 rend1 () const {
return const_reverse_iterator1 (begin1 ());
}
BOOST_UBLAS_INLINE
reverse_iterator1 rbegin1 () {
return reverse_iterator1 (end1 ());
}
BOOST_UBLAS_INLINE
reverse_iterator1 rend1 () {
return reverse_iterator1 (begin1 ());
}
BOOST_UBLAS_INLINE
const_reverse_iterator2 rbegin2 () const {
return const_reverse_iterator2 (end2 ());
}
BOOST_UBLAS_INLINE
const_reverse_iterator2 rend2 () const {
return const_reverse_iterator2 (begin2 ());
}
BOOST_UBLAS_INLINE
reverse_iterator2 rbegin2 () {
return reverse_iterator2 (end2 ());
}
BOOST_UBLAS_INLINE
reverse_iterator2 rend2 () {
return reverse_iterator2 (begin2 ());
}
private:
size_type size1_;
size_type size2_;
array_type data_;
static const value_type zero_;
};
template<class T, class L, class A>
const typename mapped_matrix<T, L, A>::value_type mapped_matrix<T, L, A>::zero_ = value_type/*zero*/();
// Vector index map based sparse matrix class
template<class T, class L, class A>
class mapped_vector_of_mapped_vector:
public matrix_container<mapped_vector_of_mapped_vector<T, L, A> > {
typedef T &true_reference;
typedef T *pointer;
typedef const T *const_pointer;
typedef A array_type;
typedef const A const_array_type;
typedef L layout_type;
typedef mapped_vector_of_mapped_vector<T, L, A> self_type;
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