DriveHQ Start Menu
Cloud Drive Mapping
Folder Sync
Cloud Backup
True Drop Box
FTP/SFTP Hosting
Group Account
DriveHQ Start Menu
Online File Server
My Storage
|
Manage Shares
|
Publishes
|
Drop Boxes
|
Group Account
WebDAV Drive Mapping
Cloud Drive Home
|
WebDAV Guide
|
Drive Mapping Tool
|
Drive Mapping URL
Complete Data Backup
Backup Guide
|
Online Backup Tool
|
Cloud-to-Cloud Backup
FTP, Email & Web Service
FTP Home
|
FTP Hosting FAQ
|
Email Hosting
|
EmailManager
|
Web Hosting
Help & Resources
About
|
Enterprise Service
|
Partnership
|
Comparisons
|
Support
Quick Links
Security and Privacy
Download Software
Service Manual
Use Cases
Group Account
Online Help
Blog
Contact
Cloud Surveillance
Sign Up
Login
Features
Business Features
Online File Server
FTP Hosting
Cloud Drive Mapping
Cloud File Backup
Email Backup & Hosting
Cloud File Sharing
Folder Synchronization
Group Management
True Drop Box
Full-text Search
AD Integration/SSO
Mobile Access
IP Camera & DVR Solution
More...
Personal Features
Personal Cloud Drive
Backup All Devices
Mobile APPs
Personal Web Hosting
Sub-Account (for Kids)
Home/PC/Kids Monitoring
More...
Software
DriveHQ Drive Mapping Tool
DriveHQ FileManager
DriveHQ Online Backup
DriveHQ Mobile Apps
Pricing
Business Plans & Pricing
Personal Plans & Pricing
Price Comparison with Others
Feature Comparison with Others
Install Mobile App
Sign up
Creating account...
Invalid character in username! Only 0-9, a-z, A-Z, _, -, . allowed.
Username is required!
Invalid email address!
E-mail is required!
Password is required!
Password is invalid!
Password and confirmation do not match.
Confirm password is required!
I accept
Membership Agreement
Please read the Membership Agreement and check "I accept"!
Free Quick Sign-up
Sign-up Page
Log in
Signing in...
Username or e-mail address is required!
Password is required!
Keep me logged in
Quick Login
Forgot Password
Up
Upload
Download
Share
Publish
New Folder
New File
Copy
Cut
Delete
Paste
Rate
Upgrade
Rotate
Effect
Edit
Slide
History
// // Copyright (c) 2003 // Gunter Winkler, Joerg Walter // // Distributed under the Boost Software License, Version 1.0. (See // accompanying file LICENSE_1_0.txt or copy at // http://www.boost.org/LICENSE_1_0.txt) // // The authors gratefully acknowledge the support of // GeNeSys mbH & Co. KG in producing this work. // #ifndef _BOOST_UBLAS_VECTOR_OF_VECTOR_ #define _BOOST_UBLAS_VECTOR_OF_VECTOR_ #include <boost/type_traits.hpp> #include <boost/numeric/ublas/storage_sparse.hpp> #include <boost/numeric/ublas/matrix_sparse.hpp> // Iterators based on ideas of Jeremy Siek namespace boost { namespace numeric { namespace ublas { // uBLAS sparse vector based sparse matrix class // FIXME outer vector can be sparse type but it is completely filled template<class T, class L, class A> class generalized_vector_of_vector: public matrix_container<generalized_vector_of_vector<T, L, A> > { typedef T &true_reference; typedef T *pointer; typedef const T *const_pointer; typedef L layout_type; typedef generalized_vector_of_vector<T, L, A> self_type; public: #ifdef BOOST_UBLAS_ENABLE_PROXY_SHORTCUTS using matrix_container<self_type>::operator (); #endif typedef typename A::size_type size_type; typedef typename A::difference_type difference_type; typedef T value_type; typedef const T &const_reference; #ifndef BOOST_UBLAS_STRICT_VECTOR_SPARSE typedef T &reference; #else typedef sparse_matrix_element<self_type> reference; #endif typedef A array_type; typedef const matrix_reference<const self_type> const_closure_type; typedef matrix_reference<self_type> closure_type; typedef typename A::value_type vector_data_value_type; typedef vector_data_value_type vector_temporary_type; typedef self_type matrix_temporary_type; typedef sparse_tag storage_category; typedef typename L::orientation_category orientation_category; // Construction and destruction BOOST_UBLAS_INLINE generalized_vector_of_vector (): matrix_container<self_type> (), size1_ (0), size2_ (0), data_ (1) { const size_type sizeM = layout_type::size_M (size1_, size2_); // create size1+1 empty vector elements data_.insert_element (sizeM, vector_data_value_type ()); storage_invariants (); } BOOST_UBLAS_INLINE generalized_vector_of_vector (size_type size1, size_type size2, size_type non_zeros = 0): matrix_container<self_type> (), size1_ (size1), size2_ (size2), data_ (layout_type::size_M (size1_, size2_) + 1) { const size_type sizeM = layout_type::size_M (size1_, size2_); const size_type sizem = layout_type::size_m (size1_, size2_); for (size_type i = 0; i < sizeM; ++ i) // create size1 vector elements data_.insert_element (i, vector_data_value_type ()) .resize (sizem, false); data_.insert_element (sizeM, vector_data_value_type ()); storage_invariants (); } BOOST_UBLAS_INLINE generalized_vector_of_vector (const generalized_vector_of_vector &m): matrix_container<self_type> (), size1_ (m.size1_), size2_ (m.size2_), data_ (m.data_) { storage_invariants (); } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector (const matrix_expression<AE> &ae, size_type non_zeros = 0): matrix_container<self_type> (), size1_ (ae ().size1 ()), size2_ (ae ().size2 ()), data_ (layout_type::size_M (size1_, size2_) + 1) { const size_type sizeM = layout_type::size_M (size1_, size2_); const size_type sizem = layout_type::size_m (size1_, size2_); for (size_type i = 0; i < sizeM; ++ i) // create size1 vector elements data_.insert_element (i, vector_data_value_type ()) .resize (sizem, false); data_.insert_element (sizeM, vector_data_value_type ()); storage_invariants (); matrix_assign<scalar_assign> (*this, ae); } // Accessors BOOST_UBLAS_INLINE size_type size1 () const { return size1_; } BOOST_UBLAS_INLINE size_type size2 () const { return size2_; } BOOST_UBLAS_INLINE size_type nnz_capacity () const { size_type non_zeros = 0; for (const_vectoriterator_type itv = data_.begin (); itv != data_.end (); ++ itv) non_zeros += (*itv).nnz_capacity (); return non_zeros; } BOOST_UBLAS_INLINE size_type nnz () const { size_type non_zeros = 0; for (const_vectoriterator_type itv = data_.begin (); itv != data_.end (); ++ itv) non_zeros += (*itv).nnz (); return non_zeros; } // Storage accessors BOOST_UBLAS_INLINE const array_type &data () const { return data_; } BOOST_UBLAS_INLINE array_type &data () { return data_; } // Resizing BOOST_UBLAS_INLINE void resize (size_type size1, size_type size2, bool preserve = true) { const size_type oldM = layout_type::size_M (size1_, size2_); size1_ = size1; size2_ = size2; const size_type sizeM = layout_type::size_M (size1_, size2_); const size_type sizem = layout_type::size_m (size1_, size2_); data ().resize (sizeM + 1, preserve); if (preserve) { for (size_type i = 0; (i <= oldM) && (i < sizeM); ++ i) ref (data () [i]).resize (sizem, preserve); for (size_type i = oldM+1; i < sizeM; ++ i) // create new vector elements data_.insert_element (i, vector_data_value_type ()) .resize (sizem, false); if (sizeM > oldM) { data_.insert_element (sizeM, vector_data_value_type ()); } else { ref (data () [sizeM]).resize (0, false); } } else { for (size_type i = 0; i < sizeM; ++ i) data_.insert_element (i, vector_data_value_type ()) .resize (sizem, false); data_.insert_element (sizeM, vector_data_value_type ()); } storage_invariants (); } // Element support BOOST_UBLAS_INLINE pointer find_element (size_type i, size_type j) { return const_cast<pointer> (const_cast<const self_type&>(*this).find_element (i, j)); } BOOST_UBLAS_INLINE const_pointer find_element (size_type i, size_type j) const { const size_type elementM = layout_type::index_M (i, j); const size_type elementm = layout_type::index_m (i, j); // optimise: check the storage_type and index directly if element always exists if (boost::is_convertible<typename array_type::storage_category, packed_tag>::value) { return & (data () [elementM] [elementm]); } else { const typename array_type::value_type *pv = data ().find_element (elementM); if (!pv) return 0; return pv->find_element (elementm); } } // Element access BOOST_UBLAS_INLINE const_reference operator () (size_type i, size_type j) const { const_pointer p = find_element (i, j); // optimise: check the storage_type and index directly if element always exists if (boost::is_convertible<typename array_type::storage_category, packed_tag>::value) { BOOST_UBLAS_CHECK (p, internal_logic () ); return *p; } else { if (p) return *p; else return zero_; } } BOOST_UBLAS_INLINE reference operator () (size_type i, size_type j) { #ifndef BOOST_UBLAS_STRICT_MATRIX_SPARSE return at_element (i, j); #else return reference (*this, i, j); #endif } // Assignment BOOST_UBLAS_INLINE generalized_vector_of_vector &operator = (const generalized_vector_of_vector &m) { if (this != &m) { size1_ = m.size1_; size2_ = m.size2_; data () = m.data (); } storage_invariants (); return *this; } BOOST_UBLAS_INLINE generalized_vector_of_vector &assign_temporary (generalized_vector_of_vector &m) { swap (m); return *this; } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector &operator = (const matrix_expression<AE> &ae) { self_type temporary (ae); return assign_temporary (temporary); } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector &assign (const matrix_expression<AE> &ae) { matrix_assign<scalar_assign> (*this, ae); return *this; } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector& operator += (const matrix_expression<AE> &ae) { self_type temporary (*this + ae); return assign_temporary (temporary); } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector &plus_assign (const matrix_expression<AE> &ae) { matrix_assign<scalar_plus_assign> (*this, ae); return *this; } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector& operator -= (const matrix_expression<AE> &ae) { self_type temporary (*this - ae); return assign_temporary (temporary); } template<class AE> BOOST_UBLAS_INLINE generalized_vector_of_vector &minus_assign (const matrix_expression<AE> &ae) { matrix_assign<scalar_minus_assign> (*this, ae); return *this; } template<class AT> BOOST_UBLAS_INLINE generalized_vector_of_vector& operator *= (const AT &at) { matrix_assign_scalar<scalar_multiplies_assign> (*this, at); return *this; } template<class AT> BOOST_UBLAS_INLINE generalized_vector_of_vector& operator /= (const AT &at) { matrix_assign_scalar<scalar_divides_assign> (*this, at); return *this; } // Swapping BOOST_UBLAS_INLINE void swap (generalized_vector_of_vector &m) { if (this != &m) { std::swap (size1_, m.size1_); std::swap (size2_, m.size2_); data ().swap (m.data ()); } storage_invariants (); } BOOST_UBLAS_INLINE friend void swap (generalized_vector_of_vector &m1, generalized_vector_of_vector &m2) { m1.swap (m2); } // Sorting void sort () { vectoriterator_type itv (data ().begin ()); vectoriterator_type itv_end (data ().end ()); while (itv != itv_end) { (*itv).sort (); ++ itv; } } // Element insertion and erasure BOOST_UBLAS_INLINE true_reference insert_element (size_type i, size_type j, const_reference t) { const size_type elementM = layout_type::index_M (i, j); const size_type elementm = layout_type::index_m (i, j); vector_data_value_type& vd (ref (data () [elementM])); storage_invariants (); return vd.insert_element (elementm, t); } BOOST_UBLAS_INLINE void append_element (size_type i, size_type j, const_reference t) { const size_type elementM = layout_type::index_M (i, j); const size_type elementm = layout_type::index_m (i, j); vector_data_value_type& vd (ref (data () [elementM])); storage_invariants (); return vd.append_element (elementm, t); } BOOST_UBLAS_INLINE void erase_element (size_type i, size_type j) { vectoriterator_type itv (data ().find (layout_type::index_M (i, j))); if (itv == data ().end ()) return; (*itv).erase_element (layout_type::index_m (i, j)); storage_invariants (); } BOOST_UBLAS_INLINE void clear () { const size_type sizeM = layout_type::size_M (size1_, size2_); // FIXME should clear data () if this is done via value_type/*zero*/() then it is not size preserving for (size_type i = 0; i < sizeM; ++ i) ref (data () [i]).clear (); storage_invariants (); } // Iterator types private: // Use vector iterator typedef typename A::const_iterator const_vectoriterator_type; typedef typename A::iterator vectoriterator_type; typedef typename A::value_type::const_iterator const_subiterator_type; typedef typename A::value_type::iterator subiterator_type; BOOST_UBLAS_INLINE true_reference at_element (size_type i, size_type j) { return ref (ref (data () [layout_type::index_M (i, j)]) [layout_type::index_m (i, j)]); } public: class const_iterator1; class iterator1; class const_iterator2; class iterator2; 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 This function seems to be big. So we do not let the compiler inline it. const_iterator1 find1 (int rank, size_type i, size_type j, int direction = 1) const { for (;;) { const_vectoriterator_type itv (data ().find (layout_type::index_M (i, j))); const_vectoriterator_type itv_end (data ().end ()); if (itv == itv_end) return const_iterator1 (*this, rank, i, j, itv_end, (*(-- itv)).end ()); const_subiterator_type it ((*itv).find (layout_type::index_m (i, j))); const_subiterator_type it_end ((*itv).end ()); if (rank == 0) return const_iterator1 (*this, rank, i, j, itv, it); if (it != it_end && it.index () == layout_type::index_m (i, j)) return const_iterator1 (*this, rank, i, j, itv, it); if (direction > 0) { if (layout_type::fast_i ()) { if (it == it_end) return const_iterator1 (*this, rank, i, j, itv, it); i = it.index (); } else { if (i >= size1_) return const_iterator1 (*this, rank, i, j, itv, it); ++ i; } } else /* if (direction < 0) */ { if (layout_type::fast_i ()) { if (it == (*itv).begin ()) return const_iterator1 (*this, rank, i, j, itv, it); --it; i = it.index (); } else { if (i == 0) return const_iterator1 (*this, rank, i, j, itv, it); -- i; } } } } // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. iterator1 find1 (int rank, size_type i, size_type j, int direction = 1) { for (;;) { vectoriterator_type itv (data ().find (layout_type::index_M (i, j))); vectoriterator_type itv_end (data ().end ()); if (itv == itv_end) return iterator1 (*this, rank, i, j, itv_end, (*(-- itv)).end ()); subiterator_type it ((*itv).find (layout_type::index_m (i, j))); subiterator_type it_end ((*itv).end ()); if (rank == 0) return iterator1 (*this, rank, i, j, itv, it); if (it != it_end && it.index () == layout_type::index_m (i, j)) return iterator1 (*this, rank, i, j, itv, it); if (direction > 0) { if (layout_type::fast_i ()) { if (it == it_end) return iterator1 (*this, rank, i, j, itv, it); i = it.index (); } else { if (i >= size1_) return iterator1 (*this, rank, i, j, itv, it); ++ i; } } else /* if (direction < 0) */ { if (layout_type::fast_i ()) { if (it == (*itv).begin ()) return iterator1 (*this, rank, i, j, itv, it); --it; i = it.index (); } else { if (i == 0) return iterator1 (*this, rank, i, j, itv, it); -- i; } } } } // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. const_iterator2 find2 (int rank, size_type i, size_type j, int direction = 1) const { for (;;) { const_vectoriterator_type itv (data ().find (layout_type::index_M (i, j))); const_vectoriterator_type itv_end (data ().end ()); if (itv == itv_end) return const_iterator2 (*this, rank, i, j, itv_end, (*(-- itv)).end ()); const_subiterator_type it ((*itv).find (layout_type::index_m (i, j))); const_subiterator_type it_end ((*itv).end ()); if (rank == 0) return const_iterator2 (*this, rank, i, j, itv, it); if (it != it_end && it.index () == layout_type::index_m (i, j)) return const_iterator2 (*this, rank, i, j, itv, it); if (direction > 0) { if (layout_type::fast_j ()) { if (it == it_end) return const_iterator2 (*this, rank, i, j, itv, it); j = it.index (); } else { if (j >= size2_) return const_iterator2 (*this, rank, i, j, itv, it); ++ j; } } else /* if (direction < 0) */ { if (layout_type::fast_j ()) { if (it == (*itv).begin ()) return const_iterator2 (*this, rank, i, j, itv, it); --it; j = it.index (); } else { if (j == 0) return const_iterator2 (*this, rank, i, j, itv, it); -- j; } } } } // BOOST_UBLAS_INLINE This function seems to be big. So we do not let the compiler inline it. iterator2 find2 (int rank, size_type i, size_type j, int direction = 1) { for (;;) { vectoriterator_type itv (data ().find (layout_type::index_M (i, j))); vectoriterator_type itv_end (data ().end ()); if (itv == itv_end) return iterator2 (*this, rank, i, j, itv_end, (*(-- itv)).end ()); subiterator_type it ((*itv).find (layout_type::index_m (i, j))); subiterator_type it_end ((*itv).end ()); if (rank == 0) return iterator2 (*this, rank, i, j, itv, it); if (it != it_end && it.index () == layout_type::index_m (i, j)) return iterator2 (*this, rank, i, j, itv, it); if (direction > 0) { if (layout_type::fast_j ()) { if (it == it_end) return iterator2 (*this, rank, i, j, itv, it); j = it.index (); } else { if (j >= size2_) return iterator2 (*this, rank, i, j, itv, it); ++ j; } } else /* if (direction < 0) */ { if (layout_type::fast_j ()) { if (it == (*itv).begin ()) return iterator2 (*this, rank, i, j, itv, it); --it; j = it.index (); } else { if (j == 0) return iterator2 (*this, rank, i, j, itv, it); -- j; } } } } class const_iterator1: public container_const_reference<generalized_vector_of_vector>, public bidirectional_iterator_base<sparse_bidirectional_iterator_tag, const_iterator1, value_type> { public: typedef typename generalized_vector_of_vector::difference_type difference_type; typedef typename generalized_vector_of_vector::value_type value_type; typedef typename generalized_vector_of_vector::const_reference reference; typedef const typename generalized_vector_of_vector::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> (), rank_ (), i_ (), j_ (), itv_ (), it_ () {} BOOST_UBLAS_INLINE const_iterator1 (const self_type &m, int rank, size_type i, size_type j, const const_vectoriterator_type &itv, const const_subiterator_type &it): container_const_reference<self_type> (m), rank_ (rank), i_ (i), j_ (j), itv_ (itv), it_ (it) {} BOOST_UBLAS_INLINE const_iterator1 (const iterator1 &it): container_const_reference<self_type> (it ()), rank_ (it.rank_), i_ (it.i_), j_ (it.j_), itv_ (it.itv_), it_ (it.it_) {} // Arithmetic BOOST_UBLAS_INLINE const_iterator1 &operator ++ () { if (rank_ == 1 && layout_type::fast_i ()) ++ it_; else { const self_type &m = (*this) (); i_ = index1 () + 1; if (rank_ == 1 && ++ itv_ == m.end1 ().itv_) *this = m.find1 (rank_, i_, j_, 1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index2 () != j_) *this = m.find1 (rank_, i_, j_, 1); } } return *this; } BOOST_UBLAS_INLINE const_iterator1 &operator -- () { if (rank_ == 1 && layout_type::fast_i ()) -- it_; else { const self_type &m = (*this) (); i_ = index1 () - 1; if (rank_ == 1 && -- itv_ == m.end1 ().itv_) *this = m.find1 (rank_, i_, j_, -1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index2 () != j_) *this = m.find1 (rank_, i_, j_, -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_; } 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_iterator2 begin () const { const self_type &m = (*this) (); return m.find2 (1, index1 (), 0); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif const_iterator2 end () const { const self_type &m = (*this) (); return m.find2 (1, index1 (), m.size2 ()); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif const_reverse_iterator2 rbegin () const { return const_reverse_iterator2 (end ()); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif const_reverse_iterator2 rend () const { return const_reverse_iterator2 (begin ()); } #endif // Indices BOOST_UBLAS_INLINE size_type index1 () const { BOOST_UBLAS_CHECK (*this != (*this) ().find1 (0, (*this) ().size1 (), j_), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_M (itv_.index (), it_.index ()) < (*this) ().size1 (), bad_index ()); return layout_type::index_M (itv_.index (), it_.index ()); } else { return i_; } } BOOST_UBLAS_INLINE size_type index2 () const { BOOST_UBLAS_CHECK (*this != (*this) ().find1 (0, (*this) ().size1 (), j_), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_m (itv_.index (), it_.index ()) < (*this) ().size2 (), bad_index ()); return layout_type::index_m (itv_.index (), it_.index ()); } else { return j_; } } // Assignment BOOST_UBLAS_INLINE const_iterator1 &operator = (const const_iterator1 &it) { container_const_reference<self_type>::assign (&it ()); rank_ = it.rank_; i_ = it.i_; j_ = it.j_; itv_ = it.itv_; it_ = it.it_; return *this; } // Comparison BOOST_UBLAS_INLINE bool operator == (const const_iterator1 &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_vectoriterator_type itv_; const_subiterator_type it_; }; BOOST_UBLAS_INLINE const_iterator1 begin1 () const { return find1 (0, 0, 0); } BOOST_UBLAS_INLINE const_iterator1 end1 () const { return find1 (0, size1_, 0); } class iterator1: public container_reference<generalized_vector_of_vector>, public bidirectional_iterator_base<sparse_bidirectional_iterator_tag, iterator1, value_type> { public: typedef typename generalized_vector_of_vector::difference_type difference_type; typedef typename generalized_vector_of_vector::value_type value_type; typedef typename generalized_vector_of_vector::true_reference reference; typedef typename generalized_vector_of_vector::pointer pointer; typedef iterator2 dual_iterator_type; typedef reverse_iterator2 dual_reverse_iterator_type; // Construction and destruction BOOST_UBLAS_INLINE iterator1 (): container_reference<self_type> (), rank_ (), i_ (), j_ (), itv_ (), it_ () {} BOOST_UBLAS_INLINE iterator1 (self_type &m, int rank, size_type i, size_type j, const vectoriterator_type &itv, const subiterator_type &it): container_reference<self_type> (m), rank_ (rank), i_ (i), j_ (j), itv_ (itv), it_ (it) {} // Arithmetic BOOST_UBLAS_INLINE iterator1 &operator ++ () { if (rank_ == 1 && layout_type::fast_i ()) ++ it_; else { self_type &m = (*this) (); i_ = index1 () + 1; if (rank_ == 1 && ++ itv_ == m.end1 ().itv_) *this = m.find1 (rank_, i_, j_, 1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index2 () != j_) *this = m.find1 (rank_, i_, j_, 1); } } return *this; } BOOST_UBLAS_INLINE iterator1 &operator -- () { if (rank_ == 1 && layout_type::fast_i ()) -- it_; else { self_type &m = (*this) (); i_ = index1 () - 1; if (rank_ == 1 && -- itv_ == m.end1 ().itv_) *this = m.find1 (rank_, i_, j_, -1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index2 () != j_) *this = m.find1 (rank_, i_, j_, -1); } } return *this; } // Dereference BOOST_UBLAS_INLINE true_reference operator * () const { BOOST_UBLAS_CHECK (index1 () < (*this) ().size1 (), bad_index ()); BOOST_UBLAS_CHECK (index2 () < (*this) ().size2 (), bad_index ()); if (rank_ == 1) { return *it_; } 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 iterator2 begin () const { self_type &m = (*this) (); return m.find2 (1, index1 (), 0); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif iterator2 end () const { self_type &m = (*this) (); return m.find2 (1, index1 (), m.size2 ()); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif reverse_iterator2 rbegin () const { return reverse_iterator2 (end ()); } BOOST_UBLAS_INLINE #ifdef BOOST_UBLAS_MSVC_NESTED_CLASS_RELATION typename self_type:: #endif reverse_iterator2 rend () const { return reverse_iterator2 (begin ()); } #endif // Indices BOOST_UBLAS_INLINE size_type index1 () const { BOOST_UBLAS_CHECK (*this != (*this) ().find1 (0, (*this) ().size1 (), j_), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_M (itv_.index (), it_.index ()) < (*this) ().size1 (), bad_index ()); return layout_type::index_M (itv_.index (), it_.index ()); } else { return i_; } } BOOST_UBLAS_INLINE size_type index2 () const { BOOST_UBLAS_CHECK (*this != (*this) ().find1 (0, (*this) ().size1 (), j_), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_m (itv_.index (), it_.index ()) < (*this) ().size2 (), bad_index ()); return layout_type::index_m (itv_.index (), it_.index ()); } else { return j_; } } // Assignment BOOST_UBLAS_INLINE iterator1 &operator = (const iterator1 &it) { container_reference<self_type>::assign (&it ()); rank_ = it.rank_; i_ = it.i_; j_ = it.j_; itv_ = it.itv_; it_ = it.it_; return *this; } // Comparison BOOST_UBLAS_INLINE bool operator == (const iterator1 &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_; vectoriterator_type itv_; subiterator_type it_; friend class const_iterator1; }; BOOST_UBLAS_INLINE iterator1 begin1 () { return find1 (0, 0, 0); } BOOST_UBLAS_INLINE iterator1 end1 () { return find1 (0, size1_, 0); } class const_iterator2: public container_const_reference<generalized_vector_of_vector>, public bidirectional_iterator_base<sparse_bidirectional_iterator_tag, const_iterator2, value_type> { public: typedef typename generalized_vector_of_vector::difference_type difference_type; typedef typename generalized_vector_of_vector::value_type value_type; typedef typename generalized_vector_of_vector::const_reference reference; typedef const typename generalized_vector_of_vector::pointer pointer; typedef const_iterator1 dual_iterator_type; typedef const_reverse_iterator1 dual_reverse_iterator_type; // Construction and destruction BOOST_UBLAS_INLINE const_iterator2 (): container_const_reference<self_type> (), rank_ (), i_ (), j_ (), itv_ (), it_ () {} BOOST_UBLAS_INLINE const_iterator2 (const self_type &m, int rank, size_type i, size_type j, const const_vectoriterator_type &itv, const const_subiterator_type &it): container_const_reference<self_type> (m), rank_ (rank), i_ (i), j_ (j), itv_ (itv), it_ (it) {} BOOST_UBLAS_INLINE const_iterator2 (const iterator2 &it): container_const_reference<self_type> (it ()), rank_ (it.rank_), i_ (it.i_), j_ (it.j_), itv_ (it.itv_), it_ (it.it_) {} // Arithmetic BOOST_UBLAS_INLINE const_iterator2 &operator ++ () { if (rank_ == 1 && layout_type::fast_j ()) ++ it_; else { const self_type &m = (*this) (); j_ = index2 () + 1; if (rank_ == 1 && ++ itv_ == m.end2 ().itv_) *this = m.find2 (rank_, i_, j_, 1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index1 () != i_) *this = m.find2 (rank_, i_, j_, 1); } } return *this; } BOOST_UBLAS_INLINE const_iterator2 &operator -- () { if (rank_ == 1 && layout_type::fast_j ()) -- it_; else { const self_type &m = (*this) (); j_ = index2 () - 1; if (rank_ == 1 && -- itv_ == m.end2 ().itv_) *this = m.find2 (rank_, i_, j_, -1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index1 () != i_) *this = m.find2 (rank_, i_, j_, -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_; } 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 { BOOST_UBLAS_CHECK (*this != (*this) ().find2 (0, i_, (*this) ().size2 ()), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_M (itv_.index (), it_.index ()) < (*this) ().size1 (), bad_index ()); return layout_type::index_M (itv_.index (), it_.index ()); } 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) { BOOST_UBLAS_CHECK (layout_type::index_m (itv_.index (), it_.index ()) < (*this) ().size2 (), bad_index ()); return layout_type::index_m (itv_.index (), it_.index ()); } 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_; itv_ = it.itv_; 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_vectoriterator_type itv_; 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<generalized_vector_of_vector>, public bidirectional_iterator_base<sparse_bidirectional_iterator_tag, iterator2, value_type> { public: typedef typename generalized_vector_of_vector::difference_type difference_type; typedef typename generalized_vector_of_vector::value_type value_type; typedef typename generalized_vector_of_vector::true_reference reference; typedef typename generalized_vector_of_vector::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_ (), itv_ (), it_ () {} BOOST_UBLAS_INLINE iterator2 (self_type &m, int rank, size_type i, size_type j, const vectoriterator_type &itv, const subiterator_type &it): container_reference<self_type> (m), rank_ (rank), i_ (i), j_ (j), itv_ (itv), it_ (it) {} // Arithmetic BOOST_UBLAS_INLINE iterator2 &operator ++ () { if (rank_ == 1 && layout_type::fast_j ()) ++ it_; else { self_type &m = (*this) (); j_ = index2 () + 1; if (rank_ == 1 && ++ itv_ == m.end2 ().itv_) *this = m.find2 (rank_, i_, j_, 1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index1 () != i_) *this = m.find2 (rank_, i_, j_, 1); } } return *this; } BOOST_UBLAS_INLINE iterator2 &operator -- () { if (rank_ == 1 && layout_type::fast_j ()) -- it_; else { self_type &m = (*this) (); j_ = index2 () - 1; if (rank_ == 1 && -- itv_ == m.end2 ().itv_) *this = m.find2 (rank_, i_, j_, -1); else if (rank_ == 1) { it_ = (*itv_).begin (); if (it_ == (*itv_).end () || index1 () != i_) *this = m.find2 (rank_, i_, j_, -1); } } return *this; } // Dereference BOOST_UBLAS_INLINE true_reference operator * () const { BOOST_UBLAS_CHECK (index1 () < (*this) ().size1 (), bad_index ()); BOOST_UBLAS_CHECK (index2 () < (*this) ().size2 (), bad_index ()); if (rank_ == 1) { return *it_; } 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 { BOOST_UBLAS_CHECK (*this != (*this) ().find2 (0, i_, (*this) ().size2 ()), bad_index ()); if (rank_ == 1) { BOOST_UBLAS_CHECK (layout_type::index_M (itv_.index (), it_.index ()) < (*this) ().size1 (), bad_index ()); return layout_type::index_M (itv_.index (), it_.index ()); } 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) { BOOST_UBLAS_CHECK (layout_type::index_m (itv_.index (), it_.index ()) < (*this) ().size2 (), bad_index ()); return layout_type::index_m (itv_.index (), it_.index ()); } 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_; itv_ = it.itv_; 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_; vectoriterator_type itv_; 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 ()); } // Serialization template<class Archive> void serialize(Archive & ar, const unsigned int /* file_version */){ // we need to copy to a collection_size_type to get a portable // and efficient serialization serialization::collection_size_type s1 (size1_); serialization::collection_size_type s2 (size2_); // serialize the sizes ar & serialization::make_nvp("size1",s1) & serialization::make_nvp("size2",s2); // copy the values back if loading if (Archive::is_loading::value) { size1_ = s1; size2_ = s2; } ar & serialization::make_nvp("data", data_); storage_invariants(); } private: void storage_invariants () const { BOOST_UBLAS_CHECK (layout_type::size_M (size1_, size2_) + 1 == data_.size (), internal_logic ()); BOOST_UBLAS_CHECK (data ().begin () != data ().end (), internal_logic ()); } size_type size1_; size_type size2_; array_type data_; static const value_type zero_; }; template<class T, class L, class A> const typename generalized_vector_of_vector<T, L, A>::value_type generalized_vector_of_vector<T, L, A>::zero_ = value_type/*zero*/(); }}} #endif
vector_of_vector.hpp
Page URL
File URL
Prev
24/26
Next
Download
( 50 KB )
Note: The DriveHQ service banners will NOT be displayed if the file owner is a paid member.
Comments
Total ratings:
0
Average rating:
Not Rated
Would you like to comment?
Join DriveHQ
for a free account, or
Logon
if you are already a member.
