// vector standard header #pragma once #ifndef _VECTOR_ #define _VECTOR_ #include #include #pragma pack(push,8) #pragma warning(push,3) #pragma warning(disable: 4244) _STD_BEGIN // TEMPLATE CLASS _Vector_val template class _Vector_val { // base class for vector to hold allocator _Alval protected: _Vector_val(_Alloc _Al = _Alloc()) : _Alval(_Al) { // construct allocator from _Al } typedef typename _Alloc::_TEMPLATE_MEMBER rebind<_Ty>::other _Alty; _Alty _Alval; // allocator object for values }; // TEMPLATE CLASS vector template > class vector : public _Vector_val<_Ty, _Ax> { // varying size array of values public: typedef vector<_Ty, _Ax> _Myt; typedef _Vector_val<_Ty, _Ax> _Mybase; typedef typename _Mybase::_Alty _Alloc; typedef _Alloc allocator_type; typedef typename _Alloc::size_type size_type; typedef typename _Alloc::difference_type difference_type; typedef typename _Alloc::pointer _Tptr; typedef typename _Alloc::const_pointer _Ctptr; typedef _Tptr pointer; typedef _Ctptr const_pointer; typedef typename _Alloc::reference reference; typedef typename _Alloc::const_reference const_reference; typedef typename _Alloc::value_type value_type; typedef _Ptrit iterator; typedef _Ptrit const_iterator; typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; vector() : _Mybase() { // construct empty vector _Buy(0); } explicit vector(const _Alloc& _Al) : _Mybase(_Al) { // construct empty vector with allocator _Buy(0); } explicit vector(size_type _Count) : _Mybase() { // construct from _Count * _Ty() _Ty _Val = _Ty(); // may throw if (_Buy(_Count)) _Construct_n(_Count, _Val); } vector(size_type _Count, const _Ty& _Val) : _Mybase() { // construct from _Count * _Val if (_Buy(_Count)) _Construct_n(_Count, _Val); } vector(size_type _Count, const _Ty& _Val, const _Alloc& _Al) : _Mybase(_Al) { // construct from _Count * _Val, with allocator if (_Buy(_Count)) _Construct_n(_Count, _Val); } vector(const _Myt& _Right) : _Mybase(_Right._Alval) { // construct by copying _Right if (_Buy(_Right.size())) _TRY_BEGIN _Mylast = _Ucopy(_Right.begin(), _Right.end(), _Myfirst); _CATCH_ALL _Tidy(); _RERAISE; _CATCH_END } template vector(_Iter _First, _Iter _Last) : _Mybase() { // construct from [_First, _Last) _Construct(_First, _Last, _Iter_cat(_First)); } template vector(_Iter _First, _Iter _Last, const _Alloc& _Al) : _Mybase(_Al) { // construct from [_First, _Last), with allocator _Construct(_First, _Last, _Iter_cat(_First)); } template void _Construct(_Iter _Count, _Iter _Val, _Int_iterator_tag) { // initialize with _Count * _Val size_type _Size = (size_type)_Count; if (_Buy(_Size)) _Construct_n(_Size, _Val); } template void _Construct(_Iter _First, _Iter _Last, input_iterator_tag) { // initialize with [_First, _Last), input iterators _Buy(0); _TRY_BEGIN insert(begin(), _First, _Last); _CATCH_ALL _Tidy(); _RERAISE; _CATCH_END } void _Construct_n(size_type _Count, const _Ty& _Val) { // construct from _Count * _Val _TRY_BEGIN _Mylast = _Ufill(_Myfirst, _Count, _Val); _CATCH_ALL _Tidy(); _RERAISE; _CATCH_END } ~vector() { // destroy the object _Tidy(); } _Myt& operator=(const _Myt& _Right) { // assign _Right if (this == &_Right) ; // nothing to do else if (_Right.size() == 0) clear(); // new sequence empty, free storage else if (_Right.size() <= size()) { // enough elements, copy new and destroy old pointer _Ptr = copy(_Right.begin(), _Right.end(), _Myfirst); _Destroy(_Ptr, _Mylast); _Mylast = _Myfirst + _Right.size(); } else if (_Right.size() <= capacity()) { // enough room, copy and construct new const_iterator _Where = _Right.begin() + size(); copy(_Right.begin(), _Where, _Myfirst); _Mylast = _Ucopy(_Where, _Right.end(), _Mylast); } else { // not enough room, allocate new array and construct new _Destroy(_Myfirst, _Mylast); this->_Alval.deallocate(_Myfirst, _Myend - _Myfirst); if (_Buy(_Right.size())) _Mylast = _Ucopy(_Right.begin(), _Right.end(), _Myfirst); } return (*this); } void reserve(size_type _Count) { // determine new minimum length of allocated storage if (max_size() < _Count) _Xlen(); // result too long else if (capacity() < _Count) { // not enough room, reallocate pointer _Ptr = this->_Alval.allocate(_Count, (void *)0); _TRY_BEGIN _Ucopy(begin(), end(), _Ptr); _CATCH_ALL this->_Alval.deallocate(_Ptr, _Count); _RERAISE; _CATCH_END size_type _Size = size(); if (_Myfirst != 0) { // destroy old array _Destroy(_Myfirst, _Mylast); this->_Alval.deallocate(_Myfirst, _Myend - _Myfirst); } _Myend = _Ptr + _Count; _Mylast = _Ptr + _Size; _Myfirst = _Ptr; } } size_type capacity() const { // return current length of allocated storage return (_Myfirst == 0 ? 0 : _Myend - _Myfirst); } iterator begin() { // return iterator for beginning of mutable sequence return (iterator(_Myfirst)); } const_iterator begin() const { // return iterator for beginning of nonmutable sequence return (const_iterator(_Myfirst)); } iterator end() { // return iterator for end of mutable sequence return (iterator(_Mylast)); } const_iterator end() const { // return iterator for end of nonmutable sequence return (const_iterator(_Mylast)); } reverse_iterator rbegin() { // return iterator for beginning of reversed mutable sequence return (reverse_iterator(end())); } const_reverse_iterator rbegin() const { // return iterator for beginning of reversed nonmutable sequence return (const_reverse_iterator(end())); } reverse_iterator rend() { // return iterator for end of reversed mutable sequence return (reverse_iterator(begin())); } const_reverse_iterator rend() const { // return iterator for end of reversed nonmutable sequence return (const_reverse_iterator(begin())); } void resize(size_type _Newsize) { // determine new length, padding with _Ty() elements as needed resize(_Newsize, _Ty()); } void resize(size_type _Newsize, _Ty _Val) { // determine new length, padding with _Val elements as needed if (size() < _Newsize) _Insert_n(end(), _Newsize - size(), _Val); else if (_Newsize < size()) erase(begin() + _Newsize, end()); } size_type size() const { // return length of sequence return (_Myfirst == 0 ? 0 : _Mylast - _Myfirst); } size_type max_size() const { // return maximum possible length of sequence return (this->_Alval.max_size()); } bool empty() const { // test if sequence is empty return (size() == 0); } _Alloc get_allocator() const { // return allocator object for values return (this->_Alval); } const_reference at(size_type _Off) const { // subscript nonmutable sequence with checking if (size() <= _Off) _Xran(); return (*(begin() + _Off)); } reference at(size_type _Off) { // subscript mutable sequence with checking if (size() <= _Off) _Xran(); return (*(begin() + _Off)); } reference operator[](size_type _Off) { // subscript mutable sequence return (*(begin() + _Off)); } const_reference operator[](size_type _Off) const { // subscript nonmutable sequence return (*(begin() + _Off)); } reference front() { // return first element of mutable sequence return (*begin()); } const_reference front() const { // return first element of nonmutable sequence return (*begin()); } reference back() { // return last element of mutable sequence return (*(end() - 1)); } const_reference back() const { // return last element of nonmutable sequence return (*(end() - 1)); } void push_back(const _Ty& _Val) { // insert element at end if (size() < capacity()) _Mylast = _Ufill(_Mylast, 1, _Val); else insert(end(), _Val); } void pop_back() { // erase element at end if (!empty()) { // erase last element _Destroy(_Mylast - 1, _Mylast); --_Mylast; } } template void assign(_Iter _First, _Iter _Last) { // assign [_First, _Last) _Assign(_First, _Last, _Iter_cat(_First)); } template void _Assign(_Iter _Count, _Iter _Val, _Int_iterator_tag) { // assign _Count * _Val _Assign_n((size_type)_Count, (_Ty)_Val); } template void _Assign(_Iter _First, _Iter _Last, input_iterator_tag) { // assign [_First, _Last), input iterators erase(begin(), end()); insert(begin(), _First, _Last); } void assign(size_type _Count, const _Ty& _Val) { // assign _Count * _Val _Assign_n(_Count, _Val); } iterator insert(iterator _Where, const _Ty& _Val) { // insert _Val at _Where size_type _Off = size() == 0 ? 0 : _Where - begin(); _Insert_n(_Where, (size_type)1, _Val); return (begin() + _Off); } void insert(iterator _Where, size_type _Count, const _Ty& _Val) { // insert _Count * _Val at _Where _Insert_n(_Where, _Count, _Val); } template void insert(iterator _Where, _Iter _First, _Iter _Last) { // insert [_First, _Last) at _Where _Insert(_Where, _First, _Last, _Iter_cat(_First)); } template void _Insert(iterator _Where, _Iter _First, _Iter _Last, _Int_iterator_tag) { // insert _Count * _Val at _Where _Insert_n(_Where, (size_type)_First, (_Ty)_Last); } template void _Insert(iterator _Where, _Iter _First, _Iter _Last, input_iterator_tag) { // insert [_First, _Last) at _Where, input iterators for (; _First != _Last; ++_First, ++_Where) _Where = insert(_Where, *_First); } template void _Insert(iterator _Where, _Iter _First, _Iter _Last, forward_iterator_tag) { // insert [_First, _Last) at _Where, forward iterators size_type _Count = 0; _Distance(_First, _Last, _Count); size_type _Capacity = capacity(); if (_Count == 0) ; else if (max_size() - size() < _Count) _Xlen(); // result too long else if (_Capacity < size() + _Count) { // not enough room, reallocate _Capacity = max_size() - _Capacity / 2 < _Capacity ? 0 : _Capacity + _Capacity / 2; // try to grow by 50% if (_Capacity < size() + _Count) _Capacity = size() + _Count; pointer _Newvec = this->_Alval.allocate(_Capacity, (void *)0); pointer _Ptr = _Newvec; _TRY_BEGIN _Ptr = _Ucopy(begin(), _Where, _Newvec); // copy prefix _Ptr = _Ucopy(_First, _Last, _Ptr); // add new stuff _Ucopy(_Where, end(), _Ptr); // copy suffix _CATCH_ALL _Destroy(_Newvec, _Ptr); this->_Alval.deallocate(_Newvec, _Capacity); _RERAISE; _CATCH_END _Count += size(); if (_Myfirst != 0) { // destroy and deallocate old array _Destroy(_Myfirst, _Mylast); this->_Alval.deallocate(_Myfirst, _Myend - _Myfirst); } _Myend = _Newvec + _Capacity; _Mylast = _Newvec + _Count; _Myfirst = _Newvec; } else if ((size_type)(end() - _Where) < _Count) { // new stuff spills off end _Ucopy(_Where, end(), _Where.base() + _Count); // copy suffix _Iter _Mid = _First; advance(_Mid, end() - _Where); _TRY_BEGIN _Ucopy(_Mid, _Last, _Mylast); // insert new stuff off end _CATCH_ALL _Destroy(_Where.base() + _Count, _Mylast + _Count); _RERAISE; _CATCH_END _Mylast += _Count; copy(_First, _Mid, _Where); // insert up to old end } else { // new stuff can all be assigned iterator _Oldend = end(); _Mylast = _Ucopy(_Oldend - _Count, _Oldend, _Mylast); // copy suffix copy_backward(_Where, _Oldend - _Count, _Oldend); // copy hole copy(_First, _Last, _Where); // insert into hole } } iterator erase(iterator _Where) { // erase element at where copy(_Where + 1, end(), _Where); _Destroy(_Mylast - 1, _Mylast); --_Mylast; return (_Where); } iterator erase(iterator _First, iterator _Last) { // erase [_First, _Last) if (_First != _Last) { // worth doing, copy down over hole pointer _Ptr = copy(_Last, end(), _First.base()); _Destroy(_Ptr, _Mylast); _Mylast = _Ptr; } return (_First); } void clear() { // erase all _Tidy(); } bool _Eq(const _Myt& _Right) const { // test for vector equality return (size() == _Right.size() && equal(begin(), end(), _Right.begin())); } bool _Lt(const _Myt& _Right) const { // test if this < _Right for vectors return (lexicographical_compare(begin(), end(), _Right.begin(), _Right.end())); } void swap(_Myt& _Right) { // exchange contents with _Right if (this->_Alval == _Right._Alval) { // same allocator, swap control information std::swap(_Myfirst, _Right._Myfirst); std::swap(_Mylast, _Right._Mylast); std::swap(_Myend, _Right._Myend); } else { // different allocator, do multiple assigns _Myt _Ts = *this; *this = _Right, _Right = _Ts; } } protected: void _Assign_n(size_type _Count, const _Ty& _Val) { // assign _Count * _Val _Ty _Tmp = _Val; // in case _Val is in sequence erase(begin(), end()); insert(begin(), _Count, _Tmp); } bool _Buy(size_type _Capacity) { // allocate array with _Capacity elements _Myfirst = 0, _Mylast = 0, _Myend = 0; if (_Capacity == 0) return (false); else if (max_size() < _Capacity) _Xlen(); // result too long else { // nonempty array, allocate storage _Myfirst = this->_Alval.allocate(_Capacity, (void *)0); _Mylast = _Myfirst; _Myend = _Myfirst + _Capacity; } return (true); } void _Destroy(pointer _First, pointer _Last) { // destroy [_First, _Last) using allocator _Destroy_range(_First, _Last, this->_Alval); } void _Tidy() { // free all storage if (_Myfirst != 0) { // something to free, destroy and deallocate it _Destroy(_Myfirst, _Mylast); this->_Alval.deallocate(_Myfirst, _Myend - _Myfirst); } _Myfirst = 0, _Mylast = 0, _Myend = 0; } template pointer _Ucopy(_Iter _First, _Iter _Last, pointer _Ptr) { // copy initializing [_First, _Last), using allocator return (_Uninitialized_copy(_First, _Last, _Ptr, this->_Alval)); } void _Insert_n(iterator _Where, size_type _Count, const _Ty& _Val) { // insert _Count * _Val at _Where _Ty _Tmp = _Val; // in case _Val is in sequence size_type _Capacity = capacity(); if (_Count == 0) ; else if (max_size() - size() < _Count) _Xlen(); // result too long else if (_Capacity < size() + _Count) { // not enough room, reallocate _Capacity = max_size() - _Capacity / 2 < _Capacity ? 0 : _Capacity + _Capacity / 2; // try to grow by 50% if (_Capacity < size() + _Count) _Capacity = size() + _Count; pointer _Newvec = this->_Alval.allocate(_Capacity, (void *)0); pointer _Ptr = _Newvec; _TRY_BEGIN _Ptr = _Ucopy(begin(), _Where, _Newvec); // copy prefix _Ptr = _Ufill(_Ptr, _Count, _Tmp); // add new stuff _Ucopy(_Where, end(), _Ptr); // copy suffix _CATCH_ALL _Destroy(_Newvec, _Ptr); this->_Alval.deallocate(_Newvec, _Capacity); _RERAISE; _CATCH_END _Count += size(); if (_Myfirst != 0) { // destroy and deallocate old array _Destroy(_Myfirst, _Mylast); this->_Alval.deallocate(_Myfirst, _Myend - _Myfirst); } _Myend = _Newvec + _Capacity; _Mylast = _Newvec + _Count; _Myfirst = _Newvec; } else if ((size_type)(end() - _Where) < _Count) { // new stuff spills off end _Ucopy(_Where, end(), _Where.base() + _Count); // copy suffix _TRY_BEGIN _Ufill(_Mylast, _Count - (end() - _Where), _Tmp); // insert new stuff off end _CATCH_ALL _Destroy(_Where.base() + _Count, _Mylast + _Count); _RERAISE; _CATCH_END _Mylast += _Count; fill(_Where, end() - _Count, _Tmp); // insert up to old end } else { // new stuff can all be assigned iterator _Oldend = end(); _Mylast = _Ucopy(_Oldend - _Count, _Oldend, _Mylast); // copy suffix copy_backward(_Where, _Oldend - _Count, _Oldend); // copy hole fill(_Where, _Where + _Count, _Tmp); // insert into hole } } pointer _Ufill(pointer _Ptr, size_type _Count, const _Ty &_Val) { // copy initializing _Count * _Val, using allocator _Uninitialized_fill_n(_Ptr, _Count, _Val, this->_Alval); return (_Ptr + _Count); } void _Xlen() const { // report a length_error _THROW(length_error, "vector too long"); } void _Xran() const { // report an out_of_range error _THROW(out_of_range, "invalid vector subscript"); } pointer _Myfirst; // pointer to beginning of array pointer _Mylast; // pointer to current end of sequence pointer _Myend; // pointer to end of array }; // vector TEMPLATE FUNCTIONS template inline bool operator==(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test for vector equality return (_Left._Eq(_Right)); } template inline bool operator!=(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test for vector inequality return (!(_Left == _Right)); } template inline bool operator<(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test if _Left < _Right for vectors return (_Left._Lt(_Right)); } template inline bool operator>(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test if _Left > _Right for vectors return (_Right < _Left); } template inline bool operator<=(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test if _Left <= _Right for vectors return (!(_Right < _Left)); } template inline bool operator>=(const vector<_Ty, _Alloc>& _Left, const vector<_Ty, _Alloc>& _Right) { // test if _Left >= _Right for vectors return (!(_Left < _Right)); } template inline void swap(vector<_Ty, _Alloc>& _Left, vector<_Ty, _Alloc>& _Right) { // swap _Left and _Right vectors _Left.swap(_Right); } // CLASS vector typedef unsigned _Vbase; // word type for vector representation const int _VBITS = 8 * sizeof (_Vbase); // at least CHAR_BITS bits per word typedef allocator<_Vbase> _Bool_allocator; template<> class vector<_Bool, _Bool_allocator> { // varying size array of bits public: typedef _Bool_allocator _Alloc; typedef _Alloc::size_type size_type; typedef _Alloc::difference_type _Dift; typedef std::vector<_Vbase, _Alloc> _Vbtype; typedef std::vector<_Bool, _Alloc> _Myt; typedef _Dift difference_type; typedef _Bool _Ty; typedef _Alloc allocator_type; // CLASS reference class reference { // reference to a bit within a base word public: reference() : _Mask(0), _Myptr(0) { // construct with null word pointer } reference(size_t _Off, _Vbase *_Ptr) : _Mask((_Vbase)(1 << _Off)), _Myptr(_Ptr) { // construct with bit offset _Off in word *_Ptr } reference& operator=(const reference& _Right) { // assign reference _Right to bit return (*this = bool(_Right)); } reference& operator=(bool _Val) { // assign _Val to bit if (_Val) *_Myptr |= _Mask; else *_Myptr &= ~_Mask; return (*this); } void flip() { // toggle the bit *_Myptr ^= _Mask; } bool operator~() const { // test if bit is reset return (!bool(*this)); } operator bool() const { // test if bit is set return ((*_Myptr & _Mask) != 0); } protected: _Vbase _Mask; // bit selection mask _Vbase *_Myptr; // pointer to base word }; typedef reference _Reft; typedef bool const_reference; typedef bool value_type; #define _VB_TYPENAME // CLASS const_iterator class const_iterator : public _Ranit<_Bool, _Dift, const_reference *, const_reference> { // iterator for nonmutable vector public: typedef random_access_iterator_tag iterator_category; typedef _Bool value_type; typedef _Dift difference_type; typedef const_reference *pointer; typedef const_reference reference; const_iterator() : _Myoff(0), _Myptr(0) { // construct with null pointer } const_iterator(size_t _Off, _VB_TYPENAME _Vbtype::const_iterator _Where) : _Myoff(_Off), _Myptr(_Where.base()) { // construct with offset _Off at iterator _Where } const_reference operator*() const { // return designated object return (_Reft(_Myoff, (_Vbase *)_Myptr)); } const_iterator& operator++() { // preincrement _Inc(); return (*this); } const_iterator operator++(int) { // postincrement const_iterator _Tmp = *this; _Inc(); return (_Tmp); } const_iterator& operator--() { // predecrement _Dec(); return (*this); } const_iterator operator--(int) { // postdecrement const_iterator _Tmp = *this; _Dec(); return (_Tmp); } const_iterator& operator+=(difference_type _Off) { // increment by integer _Myoff += _Off; _Myptr += _Myoff / _VBITS; _Myoff %= _VBITS; return (*this); } const_iterator operator+(difference_type _Off) const { // return this + integer const_iterator _Tmp = *this; return (_Tmp += _Off); } const_iterator& operator-=(difference_type _Off) { // decrement by integer return (*this += -_Off); } const_iterator operator-(difference_type _Off) const { // return this - integer const_iterator _Tmp = *this; return (_Tmp -= _Off); } difference_type operator-(const const_iterator _Right) const { // return difference of iterators return (_VBITS * (_Myptr - _Right._Myptr) + (difference_type)_Myoff - (difference_type)_Right._Myoff); } const_reference operator[](difference_type _Off) const { // subscript return (*(*this + _Off)); } bool operator==(const const_iterator& _Right) const { // test for iterator equality return (_Myptr == _Right._Myptr && _Myoff == _Right._Myoff); } bool operator!=(const const_iterator& _Right) const { // test for iterator inequality return (!(*this == _Right)); } bool operator<(const const_iterator& _Right) const { // test if this < _Right return (_Myptr < _Right._Myptr || _Myptr == _Right._Myptr && _Myoff < _Right._Myoff); } bool operator>(const const_iterator& _Right) const { // test if this > _Right return (_Right < *this); } bool operator<=(const const_iterator& _Right) const { // test if this <= _Right return (!(_Right < *this)); } bool operator>=(const const_iterator& _Right) const { // test if this >= _Right return (!(*this < _Right)); } friend const_iterator operator+(difference_type _Off, const const_iterator& _Right) { // return iterator + integer return (_Right + _Off); } protected: void _Dec() { // decrement bit position if (_Myoff != 0) --_Myoff; else _Myoff = _VBITS - 1, --_Myptr; } void _Inc() { // increment bit position if (_Myoff < _VBITS - 1) ++_Myoff; else _Myoff = 0, ++_Myptr; } size_t _Myoff; // offset of bit in word const _Vbase *_Myptr; // pointer to base of word array }; // CLASS iterator class iterator : public const_iterator { // iterator for mutable vector public: typedef random_access_iterator_tag iterator_category; typedef _Bool value_type; typedef _Dift difference_type; typedef _Reft *pointer; typedef _Reft reference; iterator() : const_iterator() { // construct with null pointer } iterator(size_t _Off, _VB_TYPENAME _Vbtype::iterator _Where) : const_iterator(_Off, _Where) { // construct with offset _Off at iterator _Where } reference operator*() const { // return designated object return (_Reft(_Myoff, (_Vbase *)_Myptr)); } iterator& operator++() { // preincrement _Inc(); return (*this); } iterator operator++(int) { // postincrement iterator _Tmp = *this; _Inc(); return (_Tmp); } iterator& operator--() { // predecrement _Dec(); return (*this); } iterator operator--(int) { // postdecrement iterator _Tmp = *this; _Dec(); return (_Tmp); } iterator& operator+=(difference_type _Off) { // increment by integer _Myoff += _Off; _Myptr += _Myoff / _VBITS; _Myoff %= _VBITS; return (*this); } iterator operator+(difference_type _Off) const { // return this + integer iterator _Tmp = *this; return (_Tmp += _Off); } iterator& operator-=(difference_type _Off) { // decrement by integer return (*this += -_Off); } iterator operator-(difference_type _Off) const { // return this - integer iterator _Tmp = *this; return (_Tmp -= _Off); } difference_type operator-(const iterator _Right) const { // return difference of iterators return (_VBITS * (_Myptr - _Right._Myptr) + (difference_type)_Myoff - (difference_type)_Right._Myoff); } reference operator[](difference_type _Off) const { // subscript return (*(*this + _Off)); } friend iterator operator+(difference_type _Off, const iterator& _Right) { // return iterator + integer return (_Right + _Off); } }; typedef iterator pointer; typedef const_iterator const_pointer; typedef std::reverse_iterator reverse_iterator; typedef std::reverse_iterator const_reverse_iterator; vector() : _Mysize(0), _Myvec() { // construct empty vector } explicit vector(const _Alloc& _Al) : _Mysize(0), _Myvec(_Al) { // construct empty vector, with allocator } explicit vector(size_type _Count, bool _Val = false) : _Mysize(0), _Myvec(_Nw(_Count), (_Vbase)(_Val ? -1 : 0)) { // construct from _Count * _Val _Trim(_Count); } vector(size_type _Count, bool _Val, const _Alloc& _Al) : _Mysize(0), _Myvec(_Nw(_Count), (_Vbase)(_Val ? -1 : 0), _Al) { // construct from _Count * _Val, with allocator _Trim(_Count); } template vector(_Iter _First, _Iter _Last) : _Mysize(0), _Myvec() { // construct from [_First, _Last) _BConstruct(_First, _Last, _Iter_cat(_First)); } template vector(_Iter _First, _Iter _Last, const _Alloc& _Al) : _Mysize(0), _Myvec(_Al) { // construct from [_First, _Last), with allocator _BConstruct(_First, _Last, _Iter_cat(_First)); } template void _BConstruct(_Iter _Count, _Iter _Val, _Int_iterator_tag) { // initialize from _Count * _Val size_type _Num = (size_type)_Count; _Myvec.assign(_Num, (_Ty)_Val ? -1 : 0); _Trim(_Num); } template void _BConstruct(_Iter _First, _Iter _Last, input_iterator_tag) { // initialize from [_First, _Last), input iterators insert(begin(), _First, _Last); } ~vector() { // destroy the object _Mysize = 0; } void reserve(size_type _Count) { // determine new minimum length of allocated storage _Myvec.reserve(_Nw(_Count)); } size_type capacity() const { // return current length of allocated storage return (_Myvec.capacity() * _VBITS); } iterator begin() { // return iterator for beginning of mutable sequence return (iterator(0, _Myvec.begin())); } const_iterator begin() const { // return iterator for beginning of nonmutable sequence return (const_iterator(0, _Myvec.begin())); } iterator end() { // return iterator for end of mutable sequence iterator _Tmp = begin(); if (0 < _Mysize) _Tmp += _Mysize; return (_Tmp); } const_iterator end() const { // return iterator for end of nonmutable sequence const_iterator _Tmp = begin(); if (0 < _Mysize) _Tmp += _Mysize; return (_Tmp); } reverse_iterator rbegin() { // return iterator for beginning of reversed mutable sequence return (reverse_iterator(end())); } const_reverse_iterator rbegin() const { // return iterator for beginning of reversed nonmutable sequence return (const_reverse_iterator(end())); } reverse_iterator rend() { // return iterator for end of reversed mutable sequence return (reverse_iterator(begin())); } const_reverse_iterator rend() const { // return iterator for end of reversed nonmutable sequence return (const_reverse_iterator(begin())); } void resize(size_type _Newsize, bool _Val = false) { // determine new length, padding with _Val elements as needed if (size() < _Newsize) _Insert_n(end(), _Newsize - size(), _Val); else if (_Newsize < size()) erase(begin() + _Newsize, end()); } size_type size() const { // return length of sequence return (_Mysize); } size_type max_size() const { // return maximum possible length of sequence const size_type _Maxsize = _Myvec.max_size(); return (_Maxsize < (size_type)(-1) / _VBITS ? _Maxsize * _VBITS : (size_type)(-1)); } bool empty() const { // test if sequence is empty return (size() == 0); } _Alloc get_allocator() const { // return allocator object for values return (_Myvec.get_allocator()); } const_reference at(size_type _Off) const { // subscript nonmutable sequence with checking if (size() <= _Off) _Xran(); return (*(begin() + _Off)); } reference at(size_type _Off) { // subscript mutable sequence with checking if (size() <= _Off) _Xran(); return (*(begin() + _Off)); } const_reference operator[](size_type _Off) const { // subscript nonmutable sequence return (*(begin() + _Off)); } reference operator[](size_type _Off) { // subscript mutable sequence return (*(begin() + _Off)); } reference front() { // return first element of mutable sequence return (*begin()); } const_reference front() const { // return first element of nonmutable sequence return (*begin()); } reference back() { // return last element of mutable sequence return (*(end() - 1)); } const_reference back() const { // return last element of nonmutable sequence return (*(end() - 1)); } void push_back(bool _Val) { // insert element at end insert(end(), _Val); } void pop_back() { // erase element at end if (!empty()) erase(end() - 1); } template void assign(_Iter _First, _Iter _Last) { // assign [_First, _Last) _Assign(_First, _Last, _Iter_cat(_First)); } template void _Assign(_Iter _Count, _Iter _Val, _Int_iterator_tag) { // assign _Count * _Val _Assign_n((size_type)_Count, (bool)_Val); } template void _Assign(_Iter _First, _Iter _Last, input_iterator_tag) { // assign [_First, _Last), input iterators erase(begin(), end()); insert(begin(), _First, _Last); } void assign(size_type _Count, bool _Val) { // assign _Count * _Val _Assign_n(_Count, _Val); } iterator insert(iterator _Where, bool _Val) { // insert _Val at _Where size_type _Off = _Where - begin(); _Insert_n(_Where, (size_type)1, _Val); return (begin() + _Off); } void insert(iterator _Where, size_type _Count, bool _Val) { // insert _Count * _Val at _Where _Insert_n(_Where, _Count, _Val); } template void insert(iterator _Where, _Iter _First, _Iter _Last) { // insert [_First, _Last) at _Where _Insert(_Where, _First, _Last, _Iter_cat(_First)); } template void _Insert(iterator _Where, _Iter _Count, _Iter _Val, _Int_iterator_tag) { // insert _Count * _Val at _Where _Insert_n(_Where, (size_type)_Count, (bool)_Val); } template void _Insert(iterator _Where, _Iter _First, _Iter _Last, input_iterator_tag) { // insert [_First, _Last) at _Where, input iterators size_type _Off = _Where - begin(); for (; _First != _Last; ++_First, ++_Off) insert(begin() + _Off, *_First); } template void _Insert(iterator _Where, _Iter _First, _Iter _Last, forward_iterator_tag) { // insert [_First, _Last) at _Where, forward iterators size_type _Capacity = 0; _Distance(_First, _Last, _Capacity); if (_Capacity == 0) ; else if (max_size() - size() < _Capacity) _Xlen(); // result too long else { // worth doing if (size() == 0) { // originally empty, just make room _Myvec.resize(_Nw(size() + _Capacity), 0); _Where = begin(); } else { // make room and copy down suffix size_type _Off = _Where - begin(); _Myvec.resize(_Nw(size() + _Capacity), 0); _Where = begin() + _Off; copy_backward(_Where, end(), end() + _Capacity); } copy(_First, _Last, _Where); // add new stuff _Mysize += _Capacity; } } iterator erase(iterator _Where) { // erase element at _Where copy(_Where + 1, end(), _Where); _Trim(_Mysize - 1); return (_Where); } iterator erase(iterator _First, iterator _Last) { // erase [_First, _Last) iterator _Next = copy(_Last, end(), _First); _Trim(_Next - begin()); return (_First); } void clear() { // erase all elements erase(begin(), end()); } void flip() { // toggle all elements for (_Vbtype::iterator _Next = _Myvec.begin(); _Next != _Myvec.end(); ++_Next) *_Next = (_Vbase)~*_Next; _Trim(_Mysize); } bool _Eq(const _Myt& _Right) const { // test for vector equality return (_Mysize == _Right._Mysize && _Myvec == _Right._Myvec); } bool _Lt(const _Myt& _Right) const { // test if this < _Right for vector return (lexicographical_compare(begin(), end(), _Right.begin(), _Right.end())); } void swap(_Myt& _Right) { // exchange contents with right std::swap(_Mysize, _Right._Mysize); _Myvec.swap(_Right._Myvec); } static void swap(reference _Left, reference _Right) { // swap _Left and _Right vector elements bool _Val = _Left; _Left = _Right; _Right = _Val; } protected: void _Assign_n(size_type _Count, bool _Val) { // assign _Count * _Val erase(begin(), end()); _Insert_n(begin(), _Count, _Val); } void _Insert_n(iterator _Where, size_type _Count, bool _Val) { // insert _Count * _Val at _Where if (_Count == 0) ; else if (max_size() - size() < _Count) _Xlen(); // result too long else { // worth doing if (size() == 0) { // originally empty, just make room _Myvec.resize(_Nw(size() + _Count), 0); _Where = begin(); } else { // make room and copy down suffix size_type _Off = _Where - begin(); _Myvec.resize(_Nw(size() + _Count), 0); _Where = begin() + _Off; copy_backward(_Where, end(), end() + _Count); } fill(_Where, _Where + _Count, _Val); // add new stuff _Mysize += _Count; } } static size_type _Nw(size_type _Count) { // return number of base words from number of bits return ((_Count + _VBITS - 1) / _VBITS); } void _Trim(size_type _Size) { // trim base vector to exact length in bits if (max_size() < _Size) _Xlen(); // result too long size_type _Words = _Nw(_Size); if (_Words < _Myvec.size()) _Myvec.erase(_Myvec.begin() + _Words, _Myvec.end()); _Mysize = _Size; _Size %= _VBITS; if (0 < _Size) _Myvec[_Words - 1] &= (_Vbase)((1 << _Size) - 1); } void _Xlen() const { // report a length_error _THROW(length_error, "vector too long"); } void _Xran() const { // throw an out_of_range error _THROW(out_of_range, "invalid vector subscript"); } size_type _Mysize; // current length of sequence _Vbtype _Myvec; // base vector of words }; typedef vector<_Bool, _Bool_allocator> _Bvector; _STD_END #pragma warning(default: 4244) #pragma warning(pop) #pragma pack(pop) #endif /* _VECTOR_ */ /* * Copyright (c) 1992-2001 by P.J. Plauger. ALL RIGHTS RESERVED. * Consult your license regarding permissions and restrictions. */ /* * This file is derived from software bearing the following * restrictions: * * Copyright (c) 1994 * Hewlett-Packard Company * * Permission to use, copy, modify, distribute and sell this * software and its documentation for any purpose is hereby * granted without fee, provided that the above copyright notice * appear in all copies and that both that copyright notice and * this permission notice appear in supporting documentation. * Hewlett-Packard Company makes no representations about the * suitability of this software for any purpose. It is provided * "as is" without express or implied warranty. V3.10:0009 */