📄 symmetric.hpp
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BOOST_UBLAS_CHECK (i < size1 (), bad_index ());
BOOST_UBLAS_CHECK (j < size2 (), bad_index ());
if (triangular_type::other (i, j))
return data () (i, j);
else
return data () (j, i);
}
#else
BOOST_UBLAS_INLINE
reference operator () (size_type i, size_type j) const {
BOOST_UBLAS_CHECK (i < size1 (), bad_index ());
BOOST_UBLAS_CHECK (j < size2 (), bad_index ());
if (triangular_type::other (i, j))
return data () (i, j);
else
return data () (j, i);
}
#endif
// Assignment
BOOST_UBLAS_INLINE
symmetric_adaptor &operator = (const symmetric_adaptor &m) {
matrix_assign<scalar_assign, triangular_type> (*this, m);
return *this;
}
BOOST_UBLAS_INLINE
symmetric_adaptor &assign_temporary (symmetric_adaptor &m) {
*this = m;
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor &operator = (const matrix_expression<AE> &ae) {
matrix_assign<scalar_assign, triangular_type> (*this, matrix<value_type> (ae));
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor &assign (const matrix_expression<AE> &ae) {
matrix_assign<scalar_assign, triangular_type> (*this, ae);
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor& operator += (const matrix_expression<AE> &ae) {
matrix_assign<scalar_assign, triangular_type> (*this, matrix<value_type> (*this + ae));
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor &plus_assign (const matrix_expression<AE> &ae) {
matrix_assign<scalar_plus_assign, triangular_type> (*this, ae);
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor& operator -= (const matrix_expression<AE> &ae) {
matrix_assign<scalar_assign, triangular_type> (*this, matrix<value_type> (*this - ae));
return *this;
}
template<class AE>
BOOST_UBLAS_INLINE
symmetric_adaptor &minus_assign (const matrix_expression<AE> &ae) {
matrix_assign<scalar_minus_assign, triangular_type> (*this, ae);
return *this;
}
template<class AT>
BOOST_UBLAS_INLINE
symmetric_adaptor& operator *= (const AT &at) {
matrix_assign_scalar<scalar_multiplies_assign> (*this, at);
return *this;
}
template<class AT>
BOOST_UBLAS_INLINE
symmetric_adaptor& operator /= (const AT &at) {
matrix_assign_scalar<scalar_divides_assign> (*this, at);
return *this;
}
// Closure comparison
BOOST_UBLAS_INLINE
bool same_closure (const symmetric_adaptor &sa) const {
return (*this).data ().same_closure (sa.data ());
}
// Swapping
BOOST_UBLAS_INLINE
void swap (symmetric_adaptor &m) {
if (this != &m)
matrix_swap<scalar_swap, triangular_type> (*this, m);
}
BOOST_UBLAS_INLINE
friend void swap (symmetric_adaptor &m1, symmetric_adaptor &m2) {
m1.swap (m2);
}
// Iterator types
private:
// Use matrix iterator
typedef typename M::const_iterator1 const_subiterator1_type;
typedef typename boost::mpl::if_<boost::is_const<M>,
typename M::const_iterator1,
typename M::iterator1>::type subiterator1_type;
typedef typename M::const_iterator2 const_subiterator2_type;
typedef typename boost::mpl::if_<boost::is_const<M>,
typename M::const_iterator2,
typename M::iterator2>::type subiterator2_type;
public:
#ifdef BOOST_UBLAS_USE_INDEXED_ITERATOR
typedef indexed_iterator1<self_type, packed_random_access_iterator_tag> iterator1;
typedef indexed_iterator2<self_type, packed_random_access_iterator_tag> iterator2;
typedef indexed_const_iterator1<self_type, dense_random_access_iterator_tag> const_iterator1;
typedef indexed_const_iterator2<self_type, dense_random_access_iterator_tag> const_iterator2;
#else
class const_iterator1;
class iterator1;
class const_iterator2;
class iterator2;
#endif
typedef reverse_iterator_base1<const_iterator1> const_reverse_iterator1;
typedef reverse_iterator_base1<iterator1> reverse_iterator1;
typedef reverse_iterator_base2<const_iterator2> const_reverse_iterator2;
typedef reverse_iterator_base2<iterator2> reverse_iterator2;
// Element lookup
BOOST_UBLAS_INLINE
const_iterator1 find1 (int rank, size_type i, size_type j) const {
if (triangular_type::other (i, j)) {
if (triangular_type::other (size1 (), j)) {
return const_iterator1 (*this, 0, 0,
data ().find1 (rank, i, j), data ().find1 (rank, size1 (), j),
data ().find2 (rank, size2 (), size1 ()), data ().find2 (rank, size2 (), size1 ()));
} else {
return const_iterator1 (*this, 0, 1,
data ().find1 (rank, i, j), data ().find1 (rank, j, j),
data ().find2 (rank, j, j), data ().find2 (rank, j, size1 ()));
}
} else {
if (triangular_type::other (size1 (), j)) {
return const_iterator1 (*this, 1, 0,
data ().find1 (rank, j, j), data ().find1 (rank, size1 (), j),
data ().find2 (rank, j, i), data ().find2 (rank, j, j));
} else {
return const_iterator1 (*this, 1, 1,
data ().find1 (rank, size1 (), size2 ()), data ().find1 (rank, size1 (), size2 ()),
data ().find2 (rank, j, i), data ().find2 (rank, j, size1 ()));
}
}
}
BOOST_UBLAS_INLINE
iterator1 find1 (int rank, size_type i, size_type j) {
if (rank == 1)
i = triangular_type::mutable_restrict1 (i, j);
return iterator1 (*this, data ().find1 (rank, i, j));
}
BOOST_UBLAS_INLINE
const_iterator2 find2 (int rank, size_type i, size_type j) const {
if (triangular_type::other (i, j)) {
if (triangular_type::other (i, size2 ())) {
return const_iterator2 (*this, 1, 1,
data ().find1 (rank, size2 (), size1 ()), data ().find1 (rank, size2 (), size1 ()),
data ().find2 (rank, i, j), data ().find2 (rank, i, size2 ()));
} else {
return const_iterator2 (*this, 1, 0,
data ().find1 (rank, i, i), data ().find1 (rank, size2 (), i),
data ().find2 (rank, i, j), data ().find2 (rank, i, i));
}
} else {
if (triangular_type::other (i, size2 ())) {
return const_iterator2 (*this, 0, 1,
data ().find1 (rank, j, i), data ().find1 (rank, i, i),
data ().find2 (rank, i, i), data ().find2 (rank, i, size2 ()));
} else {
return const_iterator2 (*this, 0, 0,
data ().find1 (rank, j, i), data ().find1 (rank, size2 (), i),
data ().find2 (rank, size1 (), size2 ()), data ().find2 (rank, size2 (), size2 ()));
}
}
}
BOOST_UBLAS_INLINE
iterator2 find2 (int rank, size_type i, size_type j) {
if (rank == 1)
j = triangular_type::mutable_restrict2 (i, j);
return iterator2 (*this, data ().find2 (rank, i, j));
}
// Iterators simply are indices.
#ifndef BOOST_UBLAS_USE_INDEXED_ITERATOR
class const_iterator1:
public container_const_reference<symmetric_adaptor>,
public random_access_iterator_base<typename iterator_restrict_traits<
typename const_subiterator1_type::iterator_category, dense_random_access_iterator_tag>::iterator_category,
const_iterator1, value_type> {
public:
typedef typename const_subiterator1_type::value_type value_type;
typedef typename const_subiterator1_type::difference_type difference_type;
typedef typename const_subiterator1_type::reference reference;
typedef typename const_subiterator1_type::pointer pointer;
typedef const_iterator2 dual_iterator_type;
typedef const_reverse_iterator2 dual_reverse_iterator_type;
// Construction and destruction
BOOST_UBLAS_INLINE
const_iterator1 ():
container_const_reference<self_type> (),
begin_ (-1), end_ (-1), current_ (-1),
it1_begin_ (), it1_end_ (), it1_ (),
it2_begin_ (), it2_end_ (), it2_ () {}
BOOST_UBLAS_INLINE
const_iterator1 (const self_type &m, int begin, int end,
const const_subiterator1_type &it1_begin, const const_subiterator1_type &it1_end,
const const_subiterator2_type &it2_begin, const const_subiterator2_type &it2_end):
container_const_reference<self_type> (m),
begin_ (begin), end_ (end), current_ (begin),
it1_begin_ (it1_begin), it1_end_ (it1_end), it1_ (it1_begin_),
it2_begin_ (it2_begin), it2_end_ (it2_end), it2_ (it2_begin_) {
if (current_ == 0 && it1_ == it1_end_)
current_ = 1;
if (current_ == 1 && it2_ == it2_end_)
current_ = 0;
if ((current_ == 0 && it1_ == it1_end_) ||
(current_ == 1 && it2_ == it2_end_))
current_ = end_;
BOOST_UBLAS_CHECK (current_ == end_ ||
(current_ == 0 && it1_ != it1_end_) ||
(current_ == 1 && it2_ != it2_end_), internal_logic ());
}
// FIXME cannot compile
// iterator1 does not have these members!
BOOST_UBLAS_INLINE
const_iterator1 (const iterator1 &it):
container_const_reference<self_type> (it ()),
begin_ (it.begin_), end_ (it.end_), current_ (it.current_),
it1_begin_ (it.it1_begin_), it1_end_ (it.it1_end_), it1_ (it.it1_),
it2_begin_ (it.it2_begin_), it2_end_ (it.it2_end_), it2_ (it.it2_) {
BOOST_UBLAS_CHECK (current_ == end_ ||
(current_ == 0 && it1_ != it1_end_) ||
(current_ == 1 && it2_ != it2_end_), internal_logic ());
}
// Arithmetic
BOOST_UBLAS_INLINE
const_iterator1 &operator ++ () {
BOOST_UBLAS_CHECK (current_ == 0 || current_ == 1, internal_logic ());
if (current_ == 0) {
BOOST_UBLAS_CHECK (it1_ != it1_end_, internal_logic ());
++ it1_;
if (it1_ == it1_end_ && end_ == 1) {
it2_ = it2_begin_;
current_ = 1;
}
} else /* if (current_ == 1) */ {
BOOST_UBLAS_CHECK (it2_ != it2_end_, internal_logic ());
++ it2_;
if (it2_ == it2_end_ && end_ == 0) {
it1_ = it1_begin_;
current_ = 0;
}
}
return *this;
}
BOOST_UBLAS_INLINE
const_iterator1 &operator -- () {
BOOST_UBLAS_CHECK (current_ == 0 || current_ == 1, internal_logic ());
if (current_ == 0) {
if (it1_ == it1_begin_ && begin_ == 1) {
it2_ = it2_end_;
BOOST_UBLAS_CHECK (it2_ != it2_begin_, internal_logic ());
-- it2_;
current_ = 1;
} else {
-- it1_;
}
} else /* if (current_ == 1) */ {
if (it2_ == it2_begin_ && begin_ == 0) {
it1_ = it1_end_;
BOOST_UBLAS_CHECK (it1_ != it1_begin_, internal_logic ());
-- it1_;
current_ = 0;
} else {
-- it2_;
}
}
return *this;
}
BOOST_UBLAS_INLINE
const_iterator1 &operator += (difference_type n) {
BOOST_UBLAS_CHECK (current_ == 0 || current_ == 1, internal_logic ());
if (current_ == 0) {
size_type d = (std::min) (n, it1_end_ - it1_);
it1_ += d;
n -= d;
if (n > 0 || (end_ == 1 && it1_ == it1_end_)) {
BOOST_UBLAS_CHECK (end_ == 1, external_logic ());
d = (std::min) (n, it2_end_ - it2_begin_);
it2_ = it2_begin_ + d;
n -= d;
current_ = 1;
}
} else /* if (current_ == 1) */ {
size_type d = (std::min) (n, it2_end_ - it2_);
it2_ += d;
n -= d;
if (n > 0 || (end_ == 0 && it2_ == it2_end_)) {
BOOST_UBLAS_CHECK (end_ == 0, external_logic ());
d = (std::min) (n, it1_end_ - it1_begin_);
it1_ = it1_begin_ + d;
n -= d;
current_ = 0;
}
}
BOOST_UBLAS_CHECK (n == 0, external_logic ());
return *this;
}
BOOST_UBLAS_INLINE
const_iterator1 &operator -= (difference_type n) {
BOOST_UBLAS_CHECK (current_ == 0 || current_ == 1, internal_logic ());
if (current_ == 0) {
size_type d = (std::min) (n, it1_ - it1_begin_);
it1_ -= d;
n -= d;
if (n > 0) {
BOOST_UBLAS_CHECK (end_ == 1, external_logic ());
d = (std::min) (n, it2_end_ - it2_begin_);
it2_ = it2_end_ - d;
n -= d;
current_ = 1;
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