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路径: \\game3dprogramming\materials\GameFactory\GameFactoryDemo\references\boost_1_35_0\boost\numeric\ublas\storage.hpp
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// // Copyright (c) 2000-2002 // Joerg Walter, Mathias Koch // // 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_STORAGE_H #define BOOST_UBLAS_STORAGE_H #include
#ifdef BOOST_UBLAS_SHALLOW_ARRAY_ADAPTOR #include
#endif #include
#include
#include
#include
#include
#include
namespace boost { namespace numeric { namespace ublas { // Base class for Storage Arrays - see the Barton Nackman trick template
class storage_array: private nonassignable { }; // Unbounded array - with allocator template
class unbounded_array: public storage_array
> { typedef unbounded_array
self_type; public: typedef ALLOC allocator_type; typedef typename ALLOC::size_type size_type; typedef typename ALLOC::difference_type difference_type; typedef T value_type; typedef const T &const_reference; typedef T &reference; typedef const T *const_pointer; typedef T *pointer; typedef const_pointer const_iterator; typedef pointer iterator; // Construction and destruction explicit BOOST_UBLAS_INLINE unbounded_array (const ALLOC &a = ALLOC()): alloc_ (a), size_ (0) { data_ = 0; } explicit BOOST_UBLAS_INLINE unbounded_array (size_type size, const ALLOC &a = ALLOC()): alloc_(a), size_ (size) { if (size_) { data_ = alloc_.allocate (size_); if (! detail::has_trivial_constructor
::value) { for (pointer d = data_; d != data_ + size_; ++d) alloc_.construct(d, value_type()); } } else data_ = 0; } // No value initialised, but still be default constructed BOOST_UBLAS_INLINE unbounded_array (size_type size, const value_type &init, const ALLOC &a = ALLOC()): alloc_ (a), size_ (size) { if (size_) { data_ = alloc_.allocate (size_); std::uninitialized_fill (begin(), end(), init); } else data_ = 0; } BOOST_UBLAS_INLINE unbounded_array (const unbounded_array &c): storage_array
>(), alloc_ (c.alloc_), size_ (c.size_) { if (size_) { data_ = alloc_.allocate (size_); std::uninitialized_copy (c.begin(), c.end(), begin()); } else data_ = 0; } BOOST_UBLAS_INLINE ~unbounded_array () { if (size_) { if (! detail::has_trivial_destructor
::value) { // std::_Destroy (begin(), end(), alloc_); const iterator i_end = end(); for (iterator i = begin (); i != i_end; ++i) { iterator_destroy (i); } } alloc_.deallocate (data_, size_); } } // Resizing private: BOOST_UBLAS_INLINE void resize_internal (const size_type size, const value_type init, const bool preserve) { if (size != size_) { pointer p_data = data_; if (size) { data_ = alloc_.allocate (size); if (preserve) { pointer si = p_data; pointer di = data_; if (size < size_) { for (; di != data_ + size; ++di) { alloc_.construct (di, *si); ++si; } } else { for (pointer si = p_data; si != p_data + size_; ++si) { alloc_.construct (di, *si); ++di; } for (; di != data_ + size; ++di) { alloc_.construct (di, init); } } } else { if (! detail::has_trivial_constructor
::value) { for (pointer di = data_; di != data_ + size; ++di) alloc_.construct (di, value_type()); } } } if (size_) { if (! detail::has_trivial_destructor
::value) { for (pointer si = p_data; si != p_data + size_; ++si) alloc_.destroy (si); } alloc_.deallocate (p_data, size_); } if (!size) data_ = 0; size_ = size; } } public: BOOST_UBLAS_INLINE void resize (size_type size) { resize_internal (size, value_type (), false); } BOOST_UBLAS_INLINE void resize (size_type size, value_type init) { resize_internal (size, init, true); } // Random Access Container BOOST_UBLAS_INLINE size_type max_size () const { return ALLOC ().max_size(); } BOOST_UBLAS_INLINE bool empty () const { return size_ == 0; } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Element access BOOST_UBLAS_INLINE const_reference operator [] (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE reference operator [] (size_type i) { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } // Assignment BOOST_UBLAS_INLINE unbounded_array &operator = (const unbounded_array &a) { if (this != &a) { resize (a.size_); std::copy (a.data_, a.data_ + a.size_, data_); } return *this; } BOOST_UBLAS_INLINE unbounded_array &assign_temporary (unbounded_array &a) { swap (a); return *this; } // Swapping BOOST_UBLAS_INLINE void swap (unbounded_array &a) { if (this != &a) { std::swap (size_, a.size_); std::swap (data_, a.data_); } } BOOST_UBLAS_INLINE friend void swap (unbounded_array &a1, unbounded_array &a2) { a1.swap (a2); } BOOST_UBLAS_INLINE const_iterator begin () const { return data_; } BOOST_UBLAS_INLINE const_iterator end () const { return data_ + size_; } BOOST_UBLAS_INLINE iterator begin () { return data_; } BOOST_UBLAS_INLINE iterator end () { return data_ + size_; } // Reverse iterators typedef std::reverse_iterator
const_reverse_iterator; typedef std::reverse_iterator
reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE reverse_iterator rbegin () { return reverse_iterator (end ()); } BOOST_UBLAS_INLINE reverse_iterator rend () { return reverse_iterator (begin ()); } // Allocator allocator_type get_allocator () { return alloc_; } private: friend class boost::serialization::access; // Serialization template
void serialize(Archive & ar, const unsigned int version) { serialization::collection_size_type s(size_); ar & serialization::make_nvp("size",s); if ( Archive::is_loading::value ) { resize(s); } ar & serialization::make_array(data_, s); } private: // Handle explict destroy on a (possibly indexed) iterator BOOST_UBLAS_INLINE static void iterator_destroy (iterator &i) { (&(*i)) -> ~value_type (); } ALLOC alloc_; size_type size_; pointer data_; }; // Bounded array - with allocator for size_type and difference_type template
class bounded_array: public storage_array
> { typedef bounded_array
self_type; public: // No allocator_type as ALLOC is not used for allocation typedef typename ALLOC::size_type size_type; typedef typename ALLOC::difference_type difference_type; typedef T value_type; typedef const T &const_reference; typedef T &reference; typedef const T *const_pointer; typedef T *pointer; typedef const_pointer const_iterator; typedef pointer iterator; // Construction and destruction BOOST_UBLAS_INLINE bounded_array (): size_ (0) /*, data_ ()*/ { // size 0 - use bounded_vector to default construct with size N } explicit BOOST_UBLAS_INLINE bounded_array (size_type size): size_ (size) /*, data_ ()*/ { BOOST_UBLAS_CHECK (size_ <= N, bad_size ()); // data_ (an array) elements are already default constructed } BOOST_UBLAS_INLINE bounded_array (size_type size, const value_type &init): size_ (size) /*, data_ ()*/ { BOOST_UBLAS_CHECK (size_ <= N, bad_size ()); // ISSUE elements should be value constructed here, but we must fill instead as already default constructed std::fill (begin(), end(), init) ; } BOOST_UBLAS_INLINE bounded_array (const bounded_array &c): size_ (c.size_) { // ISSUE elements should be copy constructed here, but we must copy instead as already default constructed std::copy (c.begin(), c.end(), begin()); } // Resizing BOOST_UBLAS_INLINE void resize (size_type size) { BOOST_UBLAS_CHECK (size_ <= N, bad_size ()); size_ = size; } BOOST_UBLAS_INLINE void resize (size_type size, value_type init) { BOOST_UBLAS_CHECK (size_ <= N, bad_size ()); if (size > size_) std::fill (data_ + size_, data_ + size, init); size_ = size; } // Random Access Container BOOST_UBLAS_INLINE size_type max_size () const { return ALLOC ().max_size(); } BOOST_UBLAS_INLINE bool empty () const { return size_ == 0; } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Element access BOOST_UBLAS_INLINE const_reference operator [] (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE reference operator [] (size_type i) { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } // Assignment BOOST_UBLAS_INLINE bounded_array &operator = (const bounded_array &a) { if (this != &a) { resize (a.size_); std::copy (a.data_, a.data_ + a.size_, data_); } return *this; } BOOST_UBLAS_INLINE bounded_array &assign_temporary (bounded_array &a) { *this = a; return *this; } // Swapping BOOST_UBLAS_INLINE void swap (bounded_array &a) { if (this != &a) { std::swap (size_, a.size_); std::swap_ranges (data_, data_ + (std::max) (size_, a.size_), a.data_); } } BOOST_UBLAS_INLINE friend void swap (bounded_array &a1, bounded_array &a2) { a1.swap (a2); } BOOST_UBLAS_INLINE const_iterator begin () const { return data_; } BOOST_UBLAS_INLINE const_iterator end () const { return data_ + size_; } BOOST_UBLAS_INLINE iterator begin () { return data_; } BOOST_UBLAS_INLINE iterator end () { return data_ + size_; } // Reverse iterators typedef std::reverse_iterator
const_reverse_iterator; typedef std::reverse_iterator
reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE reverse_iterator rbegin () { return reverse_iterator (end ()); } BOOST_UBLAS_INLINE reverse_iterator rend () { return reverse_iterator (begin ()); } private: // Serialization friend class boost::serialization::access; template
void serialize(Archive & ar, const unsigned int version) { serialization::collection_size_type s(size_); ar & serialization::make_nvp("size", s); if ( Archive::is_loading::value ) { if (s > N) bad_size("too large size in bounded_array::load()\n").raise(); resize(s); } ar & serialization::make_array(data_, s); } private: size_type size_; BOOST_UBLAS_BOUNDED_ARRAY_ALIGN value_type data_ [N]; }; // Array adaptor with normal deep copy semantics of elements template
class array_adaptor: public storage_array
> { typedef array_adaptor
self_type; public: typedef std::size_t size_type; typedef std::ptrdiff_t difference_type; typedef T value_type; typedef const T &const_reference; typedef T &reference; typedef const T *const_pointer; typedef T *pointer; // Construction and destruction BOOST_UBLAS_INLINE array_adaptor (): size_ (0), own_ (true), data_ (new value_type [0]) { } explicit BOOST_UBLAS_INLINE array_adaptor (size_type size): size_ (size), own_ (true), data_ (new value_type [size]) { } BOOST_UBLAS_INLINE array_adaptor (size_type size, const value_type &init): size_ (size), own_ (true), data_ (new value_type [size]) { std::fill (data_, data_ + size_, init); } BOOST_UBLAS_INLINE array_adaptor (size_type size, pointer data): size_ (size), own_ (false), data_ (data) {} BOOST_UBLAS_INLINE array_adaptor (const array_adaptor &a): storage_array
(), size_ (a.size_), own_ (true), data_ (new value_type [a.size_]) { *this = a; } BOOST_UBLAS_INLINE ~array_adaptor () { if (own_) { delete [] data_; } } // Resizing private: BOOST_UBLAS_INLINE void resize_internal (size_type size, value_type init, bool preserve = true) { if (size != size_) { pointer data = new value_type [size]; if (preserve) { std::copy (data_, data_ + (std::min) (size, size_), data); std::fill (data + (std::min) (size, size_), data + size, init); } if (own_) delete [] data_; size_ = size; own_ = true; data_ = data; } } BOOST_UBLAS_INLINE void resize_internal (size_type size, pointer data, value_type init, bool preserve = true) { if (data != data_) { if (preserve) { std::copy (data_, data_ + (std::min) (size, size_), data); std::fill (data + (std::min) (size, size_), data + size, init); } if (own_) delete [] data_; own_ = false; data_ = data; } else { std::fill (data + (std::min) (size, size_), data + size, init); } size_ = size; } public: BOOST_UBLAS_INLINE void resize (size_type size) { resize_internal (size, value_type (), false); } BOOST_UBLAS_INLINE void resize (size_type size, value_type init) { resize_internal (size, init, true); } BOOST_UBLAS_INLINE void resize (size_type size, pointer data) { resize_internal (size, data, value_type (), false); } BOOST_UBLAS_INLINE void resize (size_type size, pointer data, value_type init) { resize_internal (size, data, init, true); } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Element access BOOST_UBLAS_INLINE const_reference operator [] (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE reference operator [] (size_type i) { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } // Assignment BOOST_UBLAS_INLINE array_adaptor &operator = (const array_adaptor &a) { if (this != &a) { resize (a.size_); std::copy (a.data_, a.data_ + a.size_, data_); } return *this; } BOOST_UBLAS_INLINE array_adaptor &assign_temporary (array_adaptor &a) { if (own_ && a.own_) swap (a); else *this = a; return *this; } // Swapping BOOST_UBLAS_INLINE void swap (array_adaptor &a) { if (this != &a) { std::swap (size_, a.size_); std::swap (own_, a.own_); std::swap (data_, a.data_); } } BOOST_UBLAS_INLINE friend void swap (array_adaptor &a1, array_adaptor &a2) { a1.swap (a2); } // Iterators simply are pointers. typedef const_pointer const_iterator; BOOST_UBLAS_INLINE const_iterator begin () const { return data_; } BOOST_UBLAS_INLINE const_iterator end () const { return data_ + size_; } typedef pointer iterator; BOOST_UBLAS_INLINE iterator begin () { return data_; } BOOST_UBLAS_INLINE iterator end () { return data_ + size_; } // Reverse iterators typedef std::reverse_iterator
const_reverse_iterator; typedef std::reverse_iterator
reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE reverse_iterator rbegin () { return reverse_iterator (end ()); } BOOST_UBLAS_INLINE reverse_iterator rend () { return reverse_iterator (begin ()); } private: size_type size_; bool own_; pointer data_; }; #ifdef BOOST_UBLAS_SHALLOW_ARRAY_ADAPTOR // Array adaptor with shallow (reference) copy semantics of elements. // shared_array is used to maintain reference counts. // This class breaks the normal copy semantics for a storage container and is very dangerous! template
class shallow_array_adaptor: public storage_array
> { typedef shallow_array_adaptor
self_type; template
struct leaker { typedef void result_type; typedef TT *argument_type; BOOST_UBLAS_INLINE result_type operator () (argument_type x) {} }; public: typedef std::size_t size_type; typedef std::ptrdiff_t difference_type; typedef T value_type; typedef const T &const_reference; typedef T &reference; typedef const T *const_pointer; typedef T *pointer; // Construction and destruction BOOST_UBLAS_INLINE shallow_array_adaptor (): size_ (0), own_ (true), data_ (new value_type [0]) { } explicit BOOST_UBLAS_INLINE shallow_array_adaptor (size_type size): size_ (size), own_ (true), data_ (new value_type [size]) { } BOOST_UBLAS_INLINE shallow_array_adaptor (size_type size, const value_type &init): size_ (size), own_ (true), data_ (new value_type [size]) { std::fill (data_.get (), data_.get () + size_, init); } BOOST_UBLAS_INLINE shallow_array_adaptor (size_type size, pointer data): size_ (size), own_ (false), data_ (data, leaker
()) {} BOOST_UBLAS_INLINE shallow_array_adaptor (const shallow_array_adaptor &a): storage_array
(), size_ (a.size_), own_ (a.own_), data_ (a.data_) {} BOOST_UBLAS_INLINE ~shallow_array_adaptor () { } // Resizing private: BOOST_UBLAS_INLINE void resize_internal (size_type size, value_type init, bool preserve = true) { if (size != size_) { shared_array
data (new value_type [size]); if (preserve) { std::copy (data_.get (), data_.get () + (std::min) (size, size_), data.get ()); std::fill (data.get () + (std::min) (size, size_), data.get () + size, init); } size_ = size; data_ = data; } } BOOST_UBLAS_INLINE void resize_internal (size_type size, pointer data, value_type init, bool preserve = true) { if (preserve) { std::copy (data_.get (), data_.get () + (std::min) (size, size_), data); std::fill (data + (std::min) (size, size_), data + size, init); } size_ = size; data_ = data; } public: BOOST_UBLAS_INLINE void resize (size_type size) { resize_internal (size, value_type (), false); } BOOST_UBLAS_INLINE void resize (size_type size, value_type init) { resize_internal (size, init, true); } BOOST_UBLAS_INLINE void resize (size_type size, pointer data) { resize_internal (size, data, value_type (), false); } BOOST_UBLAS_INLINE void resize (size_type size, pointer data, value_type init) { resize_internal (size, data, init, true); } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Element access BOOST_UBLAS_INLINE const_reference operator [] (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE reference operator [] (size_type i) { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } // Assignment BOOST_UBLAS_INLINE shallow_array_adaptor &operator = (const shallow_array_adaptor &a) { if (this != &a) { resize (a.size_); std::copy (a.data_.get (), a.data_.get () + a.size_, data_.get ()); } return *this; } BOOST_UBLAS_INLINE shallow_array_adaptor &assign_temporary (shallow_array_adaptor &a) { if (own_ && a.own_) swap (a); else *this = a; return *this; } // Swapping BOOST_UBLAS_INLINE void swap (shallow_array_adaptor &a) { if (this != &a) { std::swap (size_, a.size_); std::swap (own_, a.own_); std::swap (data_, a.data_); } } BOOST_UBLAS_INLINE friend void swap (shallow_array_adaptor &a1, shallow_array_adaptor &a2) { a1.swap (a2); } // Iterators simply are pointers. typedef const_pointer const_iterator; BOOST_UBLAS_INLINE const_iterator begin () const { return data_.get (); } BOOST_UBLAS_INLINE const_iterator end () const { return data_.get () + size_; } typedef pointer iterator; BOOST_UBLAS_INLINE iterator begin () { return data_.get (); } BOOST_UBLAS_INLINE iterator end () { return data_.get () + size_; } // Reverse iterators typedef std::reverse_iterator
const_reverse_iterator; typedef std::reverse_iterator
reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE reverse_iterator rbegin () { return reverse_iterator (end ()); } BOOST_UBLAS_INLINE reverse_iterator rend () { return reverse_iterator (begin ()); } private: size_type size_; bool own_; shared_array
data_; }; #endif // Range class template
class basic_range { typedef basic_range
self_type; public: typedef Z size_type; typedef D difference_type; typedef size_type value_type; typedef value_type const_reference; typedef const_reference reference; typedef const value_type *const_pointer; typedef value_type *pointer; // Construction and destruction BOOST_UBLAS_INLINE basic_range (): start_ (0), size_ (0) {} BOOST_UBLAS_INLINE basic_range (size_type start, size_type stop): start_ (start), size_ (stop - start) { BOOST_UBLAS_CHECK (start_ <= stop, bad_index ()); } BOOST_UBLAS_INLINE size_type start () const { return start_; } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Random Access Container BOOST_UBLAS_INLINE size_type max_size () const { return size_; } BOOST_UBLAS_INLINE bool empty () const { return size_ == 0; } // Element access BOOST_UBLAS_INLINE const_reference operator () (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return start_ + i; } // Composition BOOST_UBLAS_INLINE basic_range compose (const basic_range &r) const { return basic_range (start_ + r.start_, start_ + r.start_ + r.size_); } // Comparison BOOST_UBLAS_INLINE bool operator == (const basic_range &r) const { return start_ == r.start_ && size_ == r.size_; } BOOST_UBLAS_INLINE bool operator != (const basic_range &r) const { return ! (*this == r); } // Iterator types private: // Use and index typedef size_type const_subiterator_type; public: #ifdef BOOST_UBLAS_USE_INDEXED_ITERATOR typedef indexed_const_iterator
const_iterator; #else class const_iterator: public container_const_reference
, public random_access_iterator_base
{ public: typedef typename basic_range::value_type value_type; typedef typename basic_range::difference_type difference_type; typedef typename basic_range::const_reference reference; typedef typename basic_range::const_pointer pointer; // Construction and destruction BOOST_UBLAS_INLINE const_iterator (): container_const_reference
(), it_ () {} BOOST_UBLAS_INLINE const_iterator (const basic_range &r, const const_subiterator_type &it): container_const_reference
(r), it_ (it) {} // Arithmetic BOOST_UBLAS_INLINE const_iterator &operator ++ () { ++ it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -- () { BOOST_UBLAS_CHECK (it_ > 0, bad_index ()); -- it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator += (difference_type n) { BOOST_UBLAS_CHECK (n >= 0 || it_ >= size_type(-n), bad_index ()); it_ += n; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -= (difference_type n) { BOOST_UBLAS_CHECK (n <= 0 || it_ >= size_type(n), bad_index ()); it_ -= n; return *this; } BOOST_UBLAS_INLINE difference_type operator - (const const_iterator &it) const { return it_ - it.it_; } // Dereference BOOST_UBLAS_INLINE const_reference operator * () const { BOOST_UBLAS_CHECK ((*this) ().start () <= it_, bad_index ()); BOOST_UBLAS_CHECK (it_ < (*this) ().start () + (*this) ().size (), bad_index ()); return it_; } BOOST_UBLAS_INLINE const_reference operator [] (difference_type n) const { return *(*this + n); } // Index BOOST_UBLAS_INLINE size_type index () const { BOOST_UBLAS_CHECK ((*this) ().start () <= it_, bad_index ()); BOOST_UBLAS_CHECK (it_ < (*this) ().start () + (*this) ().size (), bad_index ()); return it_ - (*this) ().start (); } // Assignment BOOST_UBLAS_INLINE const_iterator &operator = (const const_iterator &it) { // Comeau recommends... this->assign (&it ()); it_ = it.it_; return *this; } // Comparison BOOST_UBLAS_INLINE bool operator == (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ == it.it_; } BOOST_UBLAS_INLINE bool operator < (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ < it.it_; } private: const_subiterator_type it_; }; #endif BOOST_UBLAS_INLINE const_iterator begin () const { return const_iterator (*this, start_); } BOOST_UBLAS_INLINE const_iterator end () const { return const_iterator (*this, start_ + size_); } // Reverse iterator typedef std::reverse_iterator
const_reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE basic_range preprocess (size_type size) const { if (this != &all_) return *this; return basic_range (0, size); } static BOOST_UBLAS_INLINE const basic_range &all () { return all_; } private: size_type start_; size_type size_; static const basic_range all_; }; template
const basic_range
basic_range
::all_ (0, size_type (-1)); // Slice class template
class basic_slice { typedef basic_slice
self_type; public: typedef Z size_type; typedef D difference_type; typedef size_type value_type; typedef value_type const_reference; typedef const_reference reference; typedef const value_type *const_pointer; typedef value_type *pointer; // Construction and destruction BOOST_UBLAS_INLINE basic_slice (): start_ (0), stride_ (0), size_ (0) {} BOOST_UBLAS_INLINE basic_slice (size_type start, difference_type stride, size_type size): start_ (start), stride_ (stride), size_ (size) {} BOOST_UBLAS_INLINE size_type start () const { return start_; } BOOST_UBLAS_INLINE difference_type stride () const { return stride_; } BOOST_UBLAS_INLINE size_type size () const { return size_; } // Random Access Container BOOST_UBLAS_INLINE size_type max_size () const { return size_; } BOOST_UBLAS_INLINE bool empty () const { return size_ == 0; } // Element access BOOST_UBLAS_INLINE const_reference operator () (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); BOOST_UBLAS_CHECK (stride_ >= 0 || start_ >= i * -stride_, bad_index ()); return start_ + i * stride_; } // Composition BOOST_UBLAS_INLINE basic_slice compose (const basic_range
&r) const { BOOST_UBLAS_CHECK (stride_ >=0 || start_ >= -stride_ * r.start(), bad_index ()); return basic_slice (start_ + stride_ * r.start (), stride_, r.size ()); } BOOST_UBLAS_INLINE basic_slice compose (const basic_slice &s) const { BOOST_UBLAS_CHECK (stride_ >=0 || start_ >= -stride_ * s.start_, bad_index ()); return basic_slice (start_ + stride_ * s.start_, stride_ * s.stride_, s.size_); } // Comparison BOOST_UBLAS_INLINE bool operator == (const basic_slice &s) const { return start_ == s.start_ && stride_ == s.stride_ && size_ == s.size_; } BOOST_UBLAS_INLINE bool operator != (const basic_slice &s) const { return ! (*this == s); } // Iterator types private: // Use and index typedef size_type const_subiterator_type; public: #ifdef BOOST_UBLAS_USE_INDEXED_ITERATOR typedef indexed_const_iterator
const_iterator; #else class const_iterator: public container_const_reference
, public random_access_iterator_base
{ public: typedef typename basic_slice::value_type value_type; typedef typename basic_slice::difference_type difference_type; typedef typename basic_slice::const_reference reference; typedef typename basic_slice::const_pointer pointer; // Construction and destruction BOOST_UBLAS_INLINE const_iterator (): container_const_reference
(), it_ () {} BOOST_UBLAS_INLINE const_iterator (const basic_slice &s, const const_subiterator_type &it): container_const_reference
(s), it_ (it) {} // Arithmetic BOOST_UBLAS_INLINE const_iterator &operator ++ () { ++it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -- () { BOOST_UBLAS_CHECK (it_ > 0, bad_index ()); --it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator += (difference_type n) { BOOST_UBLAS_CHECK (n >= 0 || it_ >= size_type(-n), bad_index ()); it_ += n; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -= (difference_type n) { BOOST_UBLAS_CHECK (n <= 0 || it_ >= size_type(n), bad_index ()); it_ -= n; return *this; } BOOST_UBLAS_INLINE difference_type operator - (const const_iterator &it) const { return it_ - it.it_; } // Dereference BOOST_UBLAS_INLINE const_reference operator * () const { BOOST_UBLAS_CHECK (it_ < (*this) ().size (), bad_index ()); return (*this) ().start () + it_* (*this) ().stride (); } BOOST_UBLAS_INLINE const_reference operator [] (difference_type n) const { return *(*this + n); } // Index BOOST_UBLAS_INLINE size_type index () const { BOOST_UBLAS_CHECK (it_ < (*this) ().size (), bad_index ()); return it_; } // Assignment BOOST_UBLAS_INLINE const_iterator &operator = (const const_iterator &it) { // Comeau recommends... this->assign (&it ()); it_ = it.it_; return *this; } // Comparison BOOST_UBLAS_INLINE bool operator == (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ == it.it_; } BOOST_UBLAS_INLINE bool operator < (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ < it.it_; } private: const_subiterator_type it_; }; #endif BOOST_UBLAS_INLINE const_iterator begin () const { return const_iterator (*this, 0); } BOOST_UBLAS_INLINE const_iterator end () const { return const_iterator (*this, size_); } // Reverse iterator typedef std::reverse_iterator
const_reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE basic_slice preprocess (size_type size) const { if (this != &all_) return *this; return basic_slice (0, 1, size); } static BOOST_UBLAS_INLINE const basic_slice &all () { return all_; } private: size_type start_; difference_type stride_; size_type size_; static const basic_slice all_; }; template
const basic_slice
basic_slice
::all_ (0, 1, size_type (-1)); // Indirect array class template
class indirect_array { typedef indirect_array
self_type; public: typedef A array_type; typedef const A const_array_type; typedef typename A::size_type size_type; typedef typename A::difference_type difference_type; typedef typename A::value_type value_type; typedef typename A::const_reference const_reference; typedef typename A::reference reference; typedef typename A::const_pointer const_pointer; typedef typename A::pointer pointer; // Construction and destruction BOOST_UBLAS_INLINE indirect_array (): size_ (), data_ () {} explicit BOOST_UBLAS_INLINE indirect_array (size_type size): size_ (size), data_ (size) {} BOOST_UBLAS_INLINE indirect_array (size_type size, const array_type &data): size_ (size), data_ (data) {} BOOST_UBLAS_INLINE indirect_array (pointer start, pointer stop): size_ (stop - start), data_ (stop - start) { std::copy (start, stop, data_.begin ()); } BOOST_UBLAS_INLINE size_type size () const { return size_; } BOOST_UBLAS_INLINE const_array_type data () const { return data_; } BOOST_UBLAS_INLINE array_type data () { return data_; } // Random Access Container BOOST_UBLAS_INLINE size_type max_size () const { return size_; } BOOST_UBLAS_INLINE bool empty () const { return data_.size () == 0; } // Element access BOOST_UBLAS_INLINE const_reference operator () (size_type i) const { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE reference operator () (size_type i) { BOOST_UBLAS_CHECK (i < size_, bad_index ()); return data_ [i]; } BOOST_UBLAS_INLINE const_reference operator [] (size_type i) const { return (*this) (i); } BOOST_UBLAS_INLINE reference operator [] (size_type i) { return (*this) (i); } // Composition BOOST_UBLAS_INLINE indirect_array compose (const basic_range
&r) const { BOOST_UBLAS_CHECK (r.start () + r.size () <= size_, bad_size ()); array_type data (r.size ()); for (size_type i = 0; i < r.size (); ++ i) data [i] = data_ [r.start () + i]; return indirect_array (r.size (), data); } BOOST_UBLAS_INLINE indirect_array compose (const basic_slice
&s) const { BOOST_UBLAS_CHECK (s.start () + s.stride () * (s.size () - (s.size () > 0)) <= size (), bad_size ()); array_type data (s.size ()); for (size_type i = 0; i < s.size (); ++ i) data [i] = data_ [s.start () + s.stride () * i]; return indirect_array (s.size (), data); } BOOST_UBLAS_INLINE indirect_array compose (const indirect_array &ia) const { array_type data (ia.size_); for (size_type i = 0; i < ia.size_; ++ i) { BOOST_UBLAS_CHECK (ia.data_ [i] <= size_, bad_size ()); data [i] = data_ [ia.data_ [i]]; } return indirect_array (ia.size_, data); } // Comparison template
BOOST_UBLAS_INLINE bool operator == (const indirect_array
&ia) const { if (size_ != ia.size_) return false; for (size_type i = 0; i < BOOST_UBLAS_SAME (size_, ia.size_); ++ i) if (data_ [i] != ia.data_ [i]) return false; return true; } template
BOOST_UBLAS_INLINE bool operator != (const indirect_array
&ia) const { return ! (*this == ia); } // Iterator types private: // Use a index difference typedef difference_type const_subiterator_type; public: #ifdef BOOST_UBLAS_USE_INDEXED_ITERATOR typedef indexed_const_iterator
const_iterator; #else class const_iterator: public container_const_reference
, public random_access_iterator_base
{ public: typedef typename indirect_array::value_type value_type; typedef typename indirect_array::difference_type difference_type; typedef typename indirect_array::const_reference reference; typedef typename indirect_array::const_pointer pointer; // Construction and destruction BOOST_UBLAS_INLINE const_iterator (): container_const_reference
(), it_ () {} BOOST_UBLAS_INLINE const_iterator (const indirect_array &ia, const const_subiterator_type &it): container_const_reference
(ia), it_ (it) {} // Arithmetic BOOST_UBLAS_INLINE const_iterator &operator ++ () { ++ it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -- () { -- it_; return *this; } BOOST_UBLAS_INLINE const_iterator &operator += (difference_type n) { it_ += n; return *this; } BOOST_UBLAS_INLINE const_iterator &operator -= (difference_type n) { it_ -= n; return *this; } BOOST_UBLAS_INLINE difference_type operator - (const const_iterator &it) const { return it_ - it.it_; } // Dereference BOOST_UBLAS_INLINE const_reference operator * () const { return (*this) () (it_); } BOOST_UBLAS_INLINE const_reference operator [] (difference_type n) const { return *(*this + n); } // Index BOOST_UBLAS_INLINE size_type index () const { return it_; } // Assignment BOOST_UBLAS_INLINE const_iterator &operator = (const const_iterator &it) { // Comeau recommends... this->assign (&it ()); it_ = it.it_; return *this; } // Comparison BOOST_UBLAS_INLINE bool operator == (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ == it.it_; } BOOST_UBLAS_INLINE bool operator < (const const_iterator &it) const { BOOST_UBLAS_CHECK ((*this) () == it (), external_logic ()); return it_ < it.it_; } private: const_subiterator_type it_; }; #endif BOOST_UBLAS_INLINE const_iterator begin () const { return const_iterator (*this, 0); } BOOST_UBLAS_INLINE const_iterator end () const { return const_iterator (*this, size_); } // Reverse iterator typedef std::reverse_iterator
const_reverse_iterator; BOOST_UBLAS_INLINE const_reverse_iterator rbegin () const { return const_reverse_iterator (end ()); } BOOST_UBLAS_INLINE const_reverse_iterator rend () const { return const_reverse_iterator (begin ()); } BOOST_UBLAS_INLINE indirect_array preprocess (size_type size) const { if (this != &all_) return *this; indirect_array ia (size); for (size_type i = 0; i < size; ++ i) ia (i) = i; return ia; } static BOOST_UBLAS_INLINE const indirect_array &all () { return all_; } private: size_type size_; array_type data_; static const indirect_array all_; }; template
const indirect_array
indirect_array
::all_; // Gunter Winkler contributed the classes index_pair, index_pair_array, // index_triple and index_triple_array to enable inplace sort of parallel arrays. template
class index_pair : private boost::noncopyable, public container_reference
{ typedef index_pair
self_type; public: typedef typename V::size_type size_type; BOOST_UBLAS_INLINE index_pair(V& v, size_type i) : container_reference
(v), i_(i), v1_(v.data1_[i]), v2_(v.data2_[i]), dirty_(false), is_copy_(false) {} BOOST_UBLAS_INLINE index_pair(const self_type& rhs) : container_reference
(rhs()), i_(0), v1_(rhs.v1_), v2_(rhs.v2_), dirty_(false), is_copy_(true) {} BOOST_UBLAS_INLINE ~index_pair() { if (dirty_ && (!is_copy_) ) { (*this)().data1_[i_] = v1_; (*this)().data2_[i_] = v2_; } } BOOST_UBLAS_INLINE self_type& operator=(const self_type& rhs) { v1_ = rhs.v1_; v2_ = rhs.v2_; dirty_ = true; return *this; } BOOST_UBLAS_INLINE void swap(self_type rhs) { self_type tmp(rhs); rhs = *this; *this = tmp; } BOOST_UBLAS_INLINE friend void swap(self_type lhs, self_type rhs) { lhs.swap(rhs); } BOOST_UBLAS_INLINE bool equal(const self_type& rhs) const { return (v1_ == rhs.v1_); } BOOST_UBLAS_INLINE bool less(const self_type& rhs) const { return (v1_ < rhs.v1_); } BOOST_UBLAS_INLINE friend bool operator == (const self_type& lhs, const self_type& rhs) { return lhs.equal(rhs); } BOOST_UBLAS_INLINE friend bool operator != (const self_type& lhs, const self_type& rhs) { return !lhs.equal(rhs); } BOOST_UBLAS_INLINE friend bool operator < (const self_type& lhs, const self_type& rhs) { return lhs.less(rhs); } BOOST_UBLAS_INLINE friend bool operator >= (const self_type& lhs, const self_type& rhs) { return !lhs.less(rhs); } BOOST_UBLAS_INLINE friend bool operator > (const self_type& lhs, const self_type& rhs) { return rhs.less(lhs); } BOOST_UBLAS_INLINE friend bool operator <= (const self_type& lhs, const self_type& rhs) { return !rhs.less(lhs); } private: size_type i_; typename V::value1_type v1_; typename V::value2_type v2_; bool dirty_; bool is_copy_; }; template
class index_pair_array: private boost::noncopyable { typedef index_pair_array
self_type; public: typedef typename V1::value_type value1_type; typedef typename V2::value_type value2_type; typedef typename V1::size_type size_type; typedef typename V1::difference_type difference_type; typedef index_pair
value_type; // There is nothing that can be referenced directly. Always return a copy of the index_pair typedef value_type reference; typedef const value_type const_reference; BOOST_UBLAS_INLINE index_pair_array(size_type size, V1& data1, V2& data2) : size_(size),data1_(data1),data2_(data2) {} BOOST_UBLAS_INLINE size_type size() const { return size_; } BOOST_UBLAS_INLINE const_reference operator () (size_type i) const { return value_type((*this), i); } BOOST_UBLAS_INLINE reference operator () (size_type i) { return value_type((*this), i); } typedef indexed_iterator
iterator; typedef indexed_const_iterator
const_iterator; BOOST_UBLAS_INLINE iterator begin() { return iterator( (*this), 0); } BOOST_UBLAS_INLINE iterator end() { return iterator( (*this), size()); } BOOST_UBLAS_INLINE const_iterator begin() const { return const_iterator( (*this), 0); } BOOST_UBLAS_INLINE const_iterator end() const { return const_iterator( (*this), size()); } // unnecessary function: BOOST_UBLAS_INLINE bool equal(size_type i1, size_type i2) const { return data1_[i1] == data1_[i2]; } BOOST_UBLAS_INLINE bool less(size_type i1, size_type i2) const { return data1_[i1] < data1_[i2]; } // gives a large speedup BOOST_UBLAS_INLINE friend void iter_swap(const iterator& lhs, const iterator& rhs) { const size_type i1 = lhs.index(); const size_type i2 = rhs.index(); std::swap(lhs().data1_[i1], rhs().data1_[i2]); std::swap(lhs().data2_[i1], rhs().data2_[i2]); } private: size_type size_; V1& data1_; V2& data2_; // friend class value_type; friend class index_pair
; }; template
class index_triple : private boost::noncopyable, public container_reference
{ typedef index_triple
self_type; public: typedef typename M::size_type size_type; BOOST_UBLAS_INLINE index_triple(M& m, size_type i) : container_reference
(m), i_(i), v1_(m.data1_[i]), v2_(m.data2_[i]), v3_(m.data3_[i]), dirty_(false), is_copy_(false) {} BOOST_UBLAS_INLINE index_triple(const self_type& rhs) : container_reference
(rhs()), i_(0), v1_(rhs.v1_), v2_(rhs.v2_), v3_(rhs.v3_), dirty_(false), is_copy_(true) {} BOOST_UBLAS_INLINE ~index_triple() { if (dirty_ && (!is_copy_) ) { (*this)().data1_[i_] = v1_; (*this)().data2_[i_] = v2_; (*this)().data3_[i_] = v3_; } } BOOST_UBLAS_INLINE self_type& operator=(const self_type& rhs) { v1_ = rhs.v1_; v2_ = rhs.v2_; v3_ = rhs.v3_; dirty_ = true; return *this; } BOOST_UBLAS_INLINE void swap(self_type rhs) { self_type tmp(rhs); rhs = *this; *this = tmp; } BOOST_UBLAS_INLINE friend void swap(self_type lhs, self_type rhs) { lhs.swap(rhs); } BOOST_UBLAS_INLINE bool equal(const self_type& rhs) const { return ((v1_ == rhs.v1_) && (v2_ == rhs.v2_)); } BOOST_UBLAS_INLINE bool less(const self_type& rhs) const { return ((v1_ < rhs.v1_) || (v1_ == rhs.v1_ && v2_ < rhs.v2_)); } BOOST_UBLAS_INLINE friend bool operator == (const self_type& lhs, const self_type& rhs) { return lhs.equal(rhs); } BOOST_UBLAS_INLINE friend bool operator != (const self_type& lhs, const self_type& rhs) { return !lhs.equal(rhs); } BOOST_UBLAS_INLINE friend bool operator < (const self_type& lhs, const self_type& rhs) { return lhs.less(rhs); } BOOST_UBLAS_INLINE friend bool operator >= (const self_type& lhs, const self_type& rhs) { return !lhs.less(rhs); } BOOST_UBLAS_INLINE friend bool operator > (const self_type& lhs, const self_type& rhs) { return rhs.less(lhs); } BOOST_UBLAS_INLINE friend bool operator <= (const self_type& lhs, const self_type& rhs) { return !rhs.less(lhs); } private: size_type i_; typename M::value1_type v1_; typename M::value2_type v2_; typename M::value3_type v3_; bool dirty_; bool is_copy_; }; template
class index_triple_array: private boost::noncopyable { typedef index_triple_array
self_type; public: typedef typename V1::value_type value1_type; typedef typename V2::value_type value2_type; typedef typename V3::value_type value3_type; typedef typename V1::size_type size_type; typedef typename V1::difference_type difference_type; typedef index_triple
value_type; // There is nothing that can be referenced directly. Always return a copy of the index_triple typedef value_type reference; typedef const value_type const_reference; BOOST_UBLAS_INLINE index_triple_array(size_type size, V1& data1, V2& data2, V3& data3) : size_(size),data1_(data1),data2_(data2),data3_(data3) {} BOOST_UBLAS_INLINE size_type size() const { return size_; } BOOST_UBLAS_INLINE const_reference operator () (size_type i) const { return value_type((*this), i); } BOOST_UBLAS_INLINE reference operator () (size_type i) { return value_type((*this), i); } typedef indexed_iterator
iterator; typedef indexed_const_iterator
const_iterator; BOOST_UBLAS_INLINE iterator begin() { return iterator( (*this), 0); } BOOST_UBLAS_INLINE iterator end() { return iterator( (*this), size()); } BOOST_UBLAS_INLINE const_iterator begin() const { return const_iterator( (*this), 0); } BOOST_UBLAS_INLINE const_iterator end() const { return const_iterator( (*this), size()); } // unnecessary function: BOOST_UBLAS_INLINE bool equal(size_type i1, size_type i2) const { return ((data1_[i1] == data1_[i2]) && (data2_[i1] == data2_[i2])); } BOOST_UBLAS_INLINE bool less(size_type i1, size_type i2) const { return ((data1_[i1] < data1_[i2]) || (data1_[i1] == data1_[i2] && data2_[i1] < data2_[i2])); } // gives a large speedup BOOST_UBLAS_INLINE friend void iter_swap(const iterator& lhs, const iterator& rhs) { const size_type i1 = lhs.index(); const size_type i2 = rhs.index(); std::swap(lhs().data1_[i1], rhs().data1_[i2]); std::swap(lhs().data2_[i1], rhs().data2_[i2]); std::swap(lhs().data3_[i1], rhs().data3_[i2]); } private: size_type size_; V1& data1_; V2& data2_; V3& data3_; // friend class value_type; friend class index_triple
; }; }}} #endif
storage.hpp
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