path: root/src/debug/mse/msemstdvector.h



// Copyright (c) 2015 Noah Lopez
// Use, modification, and distribution is subject to 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)

#ifndef MSEMSTDVECTOR_H
#define MSEMSTDVECTOR_H

#include "debug/mse/msemsevector.h"

#ifdef MSE_SAFER_SUBSTITUTES_DISABLED
#define MSE_MSTDVECTOR_DISABLED
#endif /*MSE_SAFER_SUBSTITUTES_DISABLED*/

namespace mse {

	namespace mstd {

#ifdef MSE_MSTDVECTOR_DISABLED
		template<class _Ty, class _A = std::allocator<_Ty> > using vector = std::vector<_Ty, _A>;

#else /*MSE_MSTDVECTOR_DISABLED*/

#ifndef _NOEXCEPT
#define _NOEXCEPT
#endif /*_NOEXCEPT*/

		template<class _Ty, class _A = std::allocator<_Ty> >
		class vector {
		public:
			typedef mse::mstd::vector<_Ty, _A> _Myt;
			typedef mse::msevector<_Ty, _A> _MV;

			typedef typename _MV::allocator_type allocator_type;
			typedef typename _MV::value_type value_type;
			typedef typename _MV::size_type size_type;
			typedef typename _MV::difference_type difference_type;
			typedef typename _MV::pointer pointer;
			typedef typename _MV::const_pointer const_pointer;
			typedef typename _MV::reference reference;
			typedef typename _MV::const_reference const_reference;

			const _MV& msevector() const { return (*m_shptr); }
			_MV& msevector() { return (*m_shptr); }
			operator const _MV() const { return msevector(); }
			operator _MV() { return msevector(); }

			explicit vector(const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_Al)) {}
			explicit vector(size_type _N) : m_shptr(std::make_shared<_MV>(_N)) {}
			explicit vector(size_type _N, const _Ty& _V, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_N, _V, _Al)) {}
			vector(_Myt&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X.msevector()))) {}
			vector(const _Myt& _X) : m_shptr(std::make_shared<_MV>(_X.msevector())) {}
			vector(_MV&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X))) {}
			vector(const _MV& _X) : m_shptr(std::make_shared<_MV>(_X)) {}
			vector(std::vector<_Ty>&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X))) {}
			vector(const std::vector<_Ty>& _X) : m_shptr(std::make_shared<_MV>(_X)) {}
			typedef typename _MV::const_iterator _It;
			vector(_It _F, _It _L, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_F, _L, _Al)) {}
			vector(const _Ty* _F, const _Ty* _L, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_F, _L, _Al)) {}
			template<class _Iter, class = typename std::enable_if<_mse_Is_iterator<_Iter>::value, void>::type>
			vector(_Iter _First, _Iter _Last) : m_shptr(std::make_shared<_MV>(_First, _Last)) {}
			template<class _Iter, class = typename std::enable_if<_mse_Is_iterator<_Iter>::value, void>::type>
			vector(_Iter _First, _Iter _Last, const _A& _Al) : m_shptr(std::make_shared<_MV>(_First, _Last, _Al)) {}

			_Myt& operator=(_MV&& _X) { m_shptr->operator=(std::move(_X)); return (*this); }
			_Myt& operator=(const _MV& _X) { m_shptr->operator=(_X); return (*this); }
			_Myt& operator=(_Myt&& _X) { m_shptr->operator=(std::move(_X.msevector())); return (*this); }
			_Myt& operator=(const _Myt& _X) { m_shptr->operator=(_X.msevector()); return (*this); }
			void reserve(size_type _Count) { m_shptr->reserve(_Count); }
			void resize(size_type _N, const _Ty& _X = _Ty()) { m_shptr->resize(_N, _X); }
			typename _MV::const_reference operator[](size_type _P) const { return m_shptr->operator[](_P); }
			typename _MV::reference operator[](size_type _P) { return m_shptr->operator[](_P); }
			void push_back(_Ty&& _X) { m_shptr->push_back(std::move(_X)); }
			void push_back(const _Ty& _X) { m_shptr->push_back(_X); }
			void pop_back() { m_shptr->pop_back(); }
			void assign(_It _F, _It _L) { m_shptr->assign(_F, _L); }
			void assign(size_type _N, const _Ty& _X = _Ty()) { m_shptr->assign(_N, _X); }
			template<class ..._Valty>
			void emplace_back(_Valty&& ..._Val) { m_shptr->emplace_back(std::forward<_Valty>(_Val)...); }
			void clear() { m_shptr->clear(); }
			void swap(_MV& _X) { m_shptr->swap(_X); }
			void swap(_Myt& _X) { m_shptr->swap(_X.msevector()); }

			vector(_XSTD initializer_list<typename _MV::value_type> _Ilist, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_Ilist, _Al)) {}
			_Myt& operator=(_XSTD initializer_list<typename _MV::value_type> _Ilist) { m_shptr->operator=(_Ilist); return (*this); }
			void assign(_XSTD initializer_list<typename _MV::value_type> _Ilist) { m_shptr->assign(_Ilist); }

			size_type capacity() const _NOEXCEPT{ return m_shptr->capacity(); }
			void shrink_to_fit() { m_shptr->shrink_to_fit(); }
			size_type size() const _NOEXCEPT{ return m_shptr->size(); }
			size_type max_size() const _NOEXCEPT{ return m_shptr->max_size(); }
			bool empty() const _NOEXCEPT{ return m_shptr->empty(); }
			_A get_allocator() const _NOEXCEPT{ return m_shptr->get_allocator(); }
			typename _MV::const_reference at(size_type _Pos) const { return m_shptr->at(_Pos); }
			typename _MV::reference at(size_type _Pos) { return m_shptr->at(_Pos); }
			typename _MV::reference front() { return m_shptr->front(); }
			typename _MV::const_reference front() const { return m_shptr->front(); }
			typename _MV::reference back() { return m_shptr->back(); }
			typename _MV::const_reference back() const { return m_shptr->back(); }

			/* Try to avoid using these whenever possible. */
			value_type *data() _NOEXCEPT {
				return m_shptr->data();
			}
			const value_type *data() const _NOEXCEPT {
				return m_shptr->data();
			}


			class const_iterator : public _MV::random_access_const_iterator_base {
			public:
				typedef typename _MV::ss_const_iterator_type::iterator_category iterator_category;
				typedef typename _MV::ss_const_iterator_type::value_type value_type;
				typedef typename _MV::ss_const_iterator_type::difference_type difference_type;
				typedef typename _MV::difference_type distance_type;	// retained
				typedef typename _MV::ss_const_iterator_type::pointer pointer;
				typedef typename _MV::ss_const_iterator_type::reference reference;

				const_iterator() {}
				const_iterator(const const_iterator& src_cref) : m_msevector_cshptr(src_cref.m_msevector_cshptr) {
					(*this) = src_cref;
				}
				~const_iterator() {}
				const typename _MV::ss_const_iterator_type& msevector_ss_const_iterator_type() const { return m_ss_const_iterator; }
				typename _MV::ss_const_iterator_type& msevector_ss_const_iterator_type() { return m_ss_const_iterator; }
				const typename _MV::ss_const_iterator_type& mvssci() const { return msevector_ss_const_iterator_type(); }
				typename _MV::ss_const_iterator_type& mvssci() { return msevector_ss_const_iterator_type(); }

				void reset() { msevector_ss_const_iterator_type().reset(); }
				bool points_to_an_item() const { return msevector_ss_const_iterator_type().points_to_an_item(); }
				bool points_to_end_marker() const { return msevector_ss_const_iterator_type().points_to_end_marker(); }
				bool points_to_beginning() const { return msevector_ss_const_iterator_type().points_to_beginning(); }
				/* has_next_item_or_end_marker() is just an alias for points_to_an_item(). */
				bool has_next_item_or_end_marker() const { return msevector_ss_const_iterator_type().has_next_item_or_end_marker(); }
				/* has_next() is just an alias for points_to_an_item() that's familiar to java programmers. */
				bool has_next() const { return msevector_ss_const_iterator_type().has_next(); }
				bool has_previous() const { return msevector_ss_const_iterator_type().has_previous(); }
				void set_to_beginning() { msevector_ss_const_iterator_type().set_to_beginning(); }
				void set_to_end_marker() { msevector_ss_const_iterator_type().set_to_end_marker(); }
				void set_to_next() { msevector_ss_const_iterator_type().set_to_next(); }
				void set_to_previous() { msevector_ss_const_iterator_type().set_to_previous(); }
				const_iterator& operator ++() { msevector_ss_const_iterator_type().operator ++(); return (*this); }
				const_iterator operator++(int) { const_iterator _Tmp = *this; ++*this; return (_Tmp); }
				const_iterator& operator --() { msevector_ss_const_iterator_type().operator --(); return (*this); }
				const_iterator operator--(int) { const_iterator _Tmp = *this; --*this; return (_Tmp); }
				void advance(typename _MV::difference_type n) { msevector_ss_const_iterator_type().advance(n); }
				void regress(typename _MV::difference_type n) { msevector_ss_const_iterator_type().regress(n); }
				const_iterator& operator +=(difference_type n) { msevector_ss_const_iterator_type().operator +=(n); return (*this); }
				const_iterator& operator -=(difference_type n) { msevector_ss_const_iterator_type().operator -=(n); return (*this); }
				const_iterator operator+(difference_type n) const { auto retval = (*this); retval += n; return retval; }
				const_iterator operator-(difference_type n) const { return ((*this) + (-n)); }
				typename _MV::difference_type operator-(const const_iterator& _Right_cref) const { return msevector_ss_const_iterator_type() - (_Right_cref.msevector_ss_const_iterator_type()); }
				typename _MV::const_reference operator*() const { return msevector_ss_const_iterator_type().operator*(); }
				typename _MV::const_reference item() const { return operator*(); }
				typename _MV::const_reference previous_item() const { return msevector_ss_const_iterator_type().previous_item(); }
				typename _MV::const_pointer operator->() const { return msevector_ss_const_iterator_type().operator->(); }
				typename _MV::const_reference operator[](typename _MV::difference_type _Off) const { return (*(*this + _Off)); }
				bool operator==(const const_iterator& _Right_cref) const { return msevector_ss_const_iterator_type().operator==(_Right_cref.msevector_ss_const_iterator_type()); }
				bool operator!=(const const_iterator& _Right_cref) const { return (!(_Right_cref == (*this))); }
				bool operator<(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() < _Right.msevector_ss_const_iterator_type()); }
				bool operator<=(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() <= _Right.msevector_ss_const_iterator_type()); }
				bool operator>(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() > _Right.msevector_ss_const_iterator_type()); }
				bool operator>=(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() >= _Right.msevector_ss_const_iterator_type()); }
				void set_to_const_item_pointer(const const_iterator& _Right_cref) { msevector_ss_const_iterator_type().set_to_const_item_pointer(_Right_cref.msevector_ss_const_iterator_type()); }
				msev_size_t position() const { return msevector_ss_const_iterator_type().position(); }
			private:
				const_iterator(std::shared_ptr<_MV> msevector_shptr) : m_msevector_cshptr(msevector_shptr) {
					m_ss_const_iterator = msevector_shptr->ss_cbegin();
				}
				std::shared_ptr<const _MV> m_msevector_cshptr;
				/* m_ss_const_iterator needs to be declared after m_msevector_cshptr so that it's destructor will be called first. */
				typename _MV::ss_const_iterator_type m_ss_const_iterator;
				friend class /*_Myt*/vector<_Ty, _A>;
				friend class iterator;
			};
			class iterator : public _MV::random_access_iterator_base {
			public:
				typedef typename _MV::ss_iterator_type::iterator_category iterator_category;
				typedef typename _MV::ss_iterator_type::value_type value_type;
				typedef typename _MV::ss_iterator_type::difference_type difference_type;
				typedef typename _MV::difference_type distance_type;	// retained
				typedef typename _MV::ss_iterator_type::pointer pointer;
				typedef typename _MV::ss_iterator_type::reference reference;

				iterator() {}
				iterator(const iterator& src_cref) : m_msevector_shptr(src_cref.m_msevector_shptr) {
					(*this) = src_cref;
				}
				~iterator() {}
				const typename _MV::ss_iterator_type& msevector_ss_iterator_type() const { return m_ss_iterator; }
				typename _MV::ss_iterator_type& msevector_ss_iterator_type() { return m_ss_iterator; }
				const typename _MV::ss_iterator_type& mvssi() const { return msevector_ss_iterator_type(); }
				typename _MV::ss_iterator_type& mvssi() { return msevector_ss_iterator_type(); }
				operator const_iterator() const {
					const_iterator retval(m_msevector_shptr);
					if (m_msevector_shptr) {
						retval.msevector_ss_const_iterator_type().set_to_beginning();
						retval.msevector_ss_const_iterator_type().advance(msev_int(msevector_ss_iterator_type().position()));
					}
					return retval;
				}

				void reset() { msevector_ss_iterator_type().reset(); }
				bool points_to_an_item() const { return msevector_ss_iterator_type().points_to_an_item(); }
				bool points_to_end_marker() const { return msevector_ss_iterator_type().points_to_end_marker(); }
				bool points_to_beginning() const { return msevector_ss_iterator_type().points_to_beginning(); }
				/* has_next_item_or_end_marker() is just an alias for points_to_an_item(). */
				bool has_next_item_or_end_marker() const { return msevector_ss_iterator_type().has_next_item_or_end_marker(); }
				/* has_next() is just an alias for points_to_an_item() that's familiar to java programmers. */
				bool has_next() const { return msevector_ss_iterator_type().has_next(); }
				bool has_previous() const { return msevector_ss_iterator_type().has_previous(); }
				void set_to_beginning() { msevector_ss_iterator_type().set_to_beginning(); }
				void set_to_end_marker() { msevector_ss_iterator_type().set_to_end_marker(); }
				void set_to_next() { msevector_ss_iterator_type().set_to_next(); }
				void set_to_previous() { msevector_ss_iterator_type().set_to_previous(); }
				iterator& operator ++() { msevector_ss_iterator_type().operator ++(); return (*this); }
				iterator operator++(int) { iterator _Tmp = *this; ++*this; return (_Tmp); }
				iterator& operator --() { msevector_ss_iterator_type().operator --(); return (*this); }
				iterator operator--(int) { iterator _Tmp = *this; --*this; return (_Tmp); }
				void advance(typename _MV::difference_type n) { msevector_ss_iterator_type().advance(n); }
				void regress(typename _MV::difference_type n) { msevector_ss_iterator_type().regress(n); }
				iterator& operator +=(difference_type n) { msevector_ss_iterator_type().operator +=(n); return (*this); }
				iterator& operator -=(difference_type n) { msevector_ss_iterator_type().operator -=(n); return (*this); }
				iterator operator+(difference_type n) const { auto retval = (*this); retval += n; return retval; }
				iterator operator-(difference_type n) const { return ((*this) + (-n)); }
				typename _MV::difference_type operator-(const iterator& _Right_cref) const { return msevector_ss_iterator_type() - (_Right_cref.msevector_ss_iterator_type()); }
				typename _MV::reference operator*() const { return msevector_ss_iterator_type().operator*(); }
				typename _MV::reference item() const { return operator*(); }
				typename _MV::reference previous_item() const { return msevector_ss_iterator_type().previous_item(); }
				typename _MV::pointer operator->() const { return msevector_ss_iterator_type().operator->(); }
				typename _MV::reference operator[](typename _MV::difference_type _Off) const { return (*(*this + _Off)); }
				bool operator==(const iterator& _Right_cref) const { return msevector_ss_iterator_type().operator==(_Right_cref.msevector_ss_iterator_type()); }
				bool operator!=(const iterator& _Right_cref) const { return (!(_Right_cref == (*this))); }
				bool operator<(const iterator& _Right) const { return (msevector_ss_iterator_type() < _Right.msevector_ss_iterator_type()); }
				bool operator<=(const iterator& _Right) const { return (msevector_ss_iterator_type() <= _Right.msevector_ss_iterator_type()); }
				bool operator>(const iterator& _Right) const { return (msevector_ss_iterator_type() > _Right.msevector_ss_iterator_type()); }
				bool operator>=(const iterator& _Right) const { return (msevector_ss_iterator_type() >= _Right.msevector_ss_iterator_type()); }
				void set_to_item_pointer(const iterator& _Right_cref) { msevector_ss_iterator_type().set_to_item_pointer(_Right_cref.msevector_ss_iterator_type()); }
				msev_size_t position() const { return msevector_ss_iterator_type().position(); }
			private:
				std::shared_ptr<_MV> m_msevector_shptr;
				/* m_ss_iterator needs to be declared after m_msevector_shptr so that it's destructor will be called first. */
				typename _MV::ss_iterator_type m_ss_iterator;
				friend class /*_Myt*/vector<_Ty, _A>;
			};

			iterator begin() {	// return iterator for beginning of mutable sequence
				iterator retval; retval.m_msevector_shptr = this->m_shptr;
				(retval.m_ss_iterator) = m_shptr->ss_begin();
				return retval;
			}
			const_iterator begin() const {	// return iterator for beginning of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_begin();
				return retval;
			}
			iterator end() {	// return iterator for end of mutable sequence
				iterator retval; retval.m_msevector_shptr = this->m_shptr;
				(retval.m_ss_iterator) = m_shptr->ss_end();
				return retval;
			}
			const_iterator end() const {	// return iterator for end of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_end();
				return retval;
			}
			const_iterator cbegin() const {	// return iterator for beginning of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_cbegin();
				return retval;
			}
			const_iterator cend() const {	// return iterator for end of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_cend();
				return retval;
			}

			typedef std::reverse_iterator<iterator> reverse_iterator;
			typedef std::reverse_iterator<const_iterator> const_reverse_iterator;

			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()));
			}
			const_reverse_iterator crbegin() const {	// return iterator for beginning of reversed nonmutable sequence
				return (rbegin());
			}
			const_reverse_iterator crend() const {	// return iterator for end of reversed nonmutable sequence
				return (rend());
			}


			vector(const const_iterator &start, const const_iterator &end, const _A& _Al = _A())
				: m_shptr(std::make_shared<_MV>(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type(), _Al)) {}
			void assign(const const_iterator &start, const const_iterator &end) {
				m_shptr->assign(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type());
			}
			void assign_inclusive(const const_iterator &first, const const_iterator &last) {
				m_shptr->assign_inclusive(first.msevector_ss_const_iterator_type(), last.msevector_ss_const_iterator_type());
			}
			iterator insert_before(const const_iterator &pos, size_type _M, const _Ty& _X) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), _M, _X);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator insert_before(const const_iterator &pos, _Ty&& _X) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), std::move(_X));
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator insert_before(const const_iterator &pos, const _Ty& _X = _Ty()) { return insert_before(pos, 1, _X); }
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert_before(const const_iterator &pos, const _Iter &start, const _Iter &end) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), start, end);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert_before_inclusive(const const_iterator &pos, const _Iter &first, const _Iter &last) {
				auto end = last; end++;
				return insert_before(pos, first, end);
			}
			iterator insert_before(const const_iterator &pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) {	// insert initializer_list
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), _Ilist);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			void insert_before(msev_size_t pos, const _Ty& _X = _Ty()) {
				m_shptr->insert_before(pos, _X);
			}
			void insert_before(msev_size_t pos, size_type _M, const _Ty& _X) {
				m_shptr->insert_before(pos, _M, _X);
			}
			void insert_before(msev_size_t pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) {	// insert initializer_list
				m_shptr->insert_before(pos, _Ilist);
			}
			/* These insert() functions are just aliases for their corresponding insert_before() functions. */
			iterator insert(const const_iterator &pos, size_type _M, const _Ty& _X) { return insert_before(pos, _M, _X); }
			iterator insert(const const_iterator &pos, _Ty&& _X) { return insert_before(pos, std::move(_X)); }
			iterator insert(const const_iterator &pos, const _Ty& _X = _Ty()) { return insert_before(pos, _X); }
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert(const const_iterator &pos, const _Iter &start, const _Iter &end) { return insert_before(pos, start, end); }
			iterator insert(const const_iterator &pos, const _Ty* start, const _Ty* end) { return insert_before(pos, start, end); }
			iterator insert(const const_iterator &pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) { return insert_before(pos, _Ilist); }
			template<class ..._Valty>
			iterator emplace(const const_iterator &pos, _Valty&& ..._Val) {
				auto res = m_shptr->emplace(pos.msevector_ss_const_iterator_type(), std::forward<_Valty>(_Val)...);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase(const const_iterator &pos) {
				auto res = m_shptr->erase(pos.msevector_ss_const_iterator_type());
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase(const const_iterator &start, const const_iterator &end) {
				auto res = m_shptr->erase(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type());
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase_inclusive(const const_iterator &first, const const_iterator &last) {
				auto end = last; end.set_to_next();
				return erase_inclusive(first, end);
			}
			bool operator==(const _Myt& _Right) const {	// test for vector equality
				return ((*(_Right.m_shptr)) == (*m_shptr));
			}
			bool operator<(const _Myt& _Right) const {	// test if _Left < _Right for vectors
				return ((*m_shptr) < (*(_Right.m_shptr)));
			}

		private:
			std::shared_ptr<_MV> m_shptr;
		};

		template<class _Ty, class _Alloc> inline bool operator!=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test for vector inequality
			return (!(_Left == _Right));
		}

		template<class _Ty, class _Alloc> inline bool operator>(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left > _Right for vectors
			return (_Right < _Left);
		}

		template<class _Ty, class _Alloc> inline bool operator<=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left <= _Right for vectors
			return (!(_Right < _Left));
		}

		template<class _Ty, class _Alloc> inline bool operator>=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left >= _Right for vectors
			return (!(_Left < _Right));
		}
#endif /*MSE_MSTDVECTOR_DISABLED*/
	}
}
#endif /*ndef MSEMSTDVECTOR_H*/
// Copyright (c) 2015 Noah Lopez
// Use, modification, and distribution is subject to 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)

#ifndef MSEMSTDVECTOR_H
#define MSEMSTDVECTOR_H

#include "debug/mse/msemsevector.h"

#ifdef MSE_SAFER_SUBSTITUTES_DISABLED
#define MSE_MSTDVECTOR_DISABLED
#endif /*MSE_SAFER_SUBSTITUTES_DISABLED*/

namespace mse {

	namespace mstd {

#ifdef MSE_MSTDVECTOR_DISABLED
		template<class _Ty, class _A = std::allocator<_Ty> > using vector = std::vector<_Ty, _A>;

#else /*MSE_MSTDVECTOR_DISABLED*/

#ifndef _NOEXCEPT
#define _NOEXCEPT
#endif /*_NOEXCEPT*/

		template<class _Ty, class _A = std::allocator<_Ty> >
		class vector {
		public:
			typedef mse::mstd::vector<_Ty, _A> _Myt;
			typedef mse::msevector<_Ty, _A> _MV;

			typedef typename _MV::allocator_type allocator_type;
			typedef typename _MV::value_type value_type;
			typedef typename _MV::size_type size_type;
			typedef typename _MV::difference_type difference_type;
			typedef typename _MV::pointer pointer;
			typedef typename _MV::const_pointer const_pointer;
			typedef typename _MV::reference reference;
			typedef typename _MV::const_reference const_reference;

			const _MV& msevector() const { return (*m_shptr); }
			_MV& msevector() { return (*m_shptr); }
			operator const _MV() const { return msevector(); }
			operator _MV() { return msevector(); }

			explicit vector(const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_Al)) {}
			explicit vector(size_type _N) : m_shptr(std::make_shared<_MV>(_N)) {}
			explicit vector(size_type _N, const _Ty& _V, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_N, _V, _Al)) {}
			vector(_Myt&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X.msevector()))) {}
			vector(const _Myt& _X) : m_shptr(std::make_shared<_MV>(_X.msevector())) {}
			vector(_MV&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X))) {}
			vector(const _MV& _X) : m_shptr(std::make_shared<_MV>(_X)) {}
			vector(std::vector<_Ty>&& _X) : m_shptr(std::make_shared<_MV>(std::move(_X))) {}
			vector(const std::vector<_Ty>& _X) : m_shptr(std::make_shared<_MV>(_X)) {}
			typedef typename _MV::const_iterator _It;
			vector(_It _F, _It _L, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_F, _L, _Al)) {}
			vector(const _Ty* _F, const _Ty* _L, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_F, _L, _Al)) {}
			template<class _Iter, class = typename std::enable_if<_mse_Is_iterator<_Iter>::value, void>::type>
			vector(_Iter _First, _Iter _Last) : m_shptr(std::make_shared<_MV>(_First, _Last)) {}
			template<class _Iter, class = typename std::enable_if<_mse_Is_iterator<_Iter>::value, void>::type>
			vector(_Iter _First, _Iter _Last, const _A& _Al) : m_shptr(std::make_shared<_MV>(_First, _Last, _Al)) {}

			_Myt& operator=(_MV&& _X) { m_shptr->operator=(std::move(_X)); return (*this); }
			_Myt& operator=(const _MV& _X) { m_shptr->operator=(_X); return (*this); }
			_Myt& operator=(_Myt&& _X) { m_shptr->operator=(std::move(_X.msevector())); return (*this); }
			_Myt& operator=(const _Myt& _X) { m_shptr->operator=(_X.msevector()); return (*this); }
			void reserve(size_type _Count) { m_shptr->reserve(_Count); }
			void resize(size_type _N, const _Ty& _X = _Ty()) { m_shptr->resize(_N, _X); }
			typename _MV::const_reference operator[](size_type _P) const { return m_shptr->operator[](_P); }
			typename _MV::reference operator[](size_type _P) { return m_shptr->operator[](_P); }
			void push_back(_Ty&& _X) { m_shptr->push_back(std::move(_X)); }
			void push_back(const _Ty& _X) { m_shptr->push_back(_X); }
			void pop_back() { m_shptr->pop_back(); }
			void assign(_It _F, _It _L) { m_shptr->assign(_F, _L); }
			void assign(size_type _N, const _Ty& _X = _Ty()) { m_shptr->assign(_N, _X); }
			template<class ..._Valty>
			void emplace_back(_Valty&& ..._Val) { m_shptr->emplace_back(std::forward<_Valty>(_Val)...); }
			void clear() { m_shptr->clear(); }
			void swap(_MV& _X) { m_shptr->swap(_X); }
			void swap(_Myt& _X) { m_shptr->swap(_X.msevector()); }

			vector(_XSTD initializer_list<typename _MV::value_type> _Ilist, const _A& _Al = _A()) : m_shptr(std::make_shared<_MV>(_Ilist, _Al)) {}
			_Myt& operator=(_XSTD initializer_list<typename _MV::value_type> _Ilist) { m_shptr->operator=(_Ilist); return (*this); }
			void assign(_XSTD initializer_list<typename _MV::value_type> _Ilist) { m_shptr->assign(_Ilist); }

			size_type capacity() const _NOEXCEPT{ return m_shptr->capacity(); }
			void shrink_to_fit() { m_shptr->shrink_to_fit(); }
			size_type size() const _NOEXCEPT{ return m_shptr->size(); }
			size_type max_size() const _NOEXCEPT{ return m_shptr->max_size(); }
			bool empty() const _NOEXCEPT{ return m_shptr->empty(); }
			_A get_allocator() const _NOEXCEPT{ return m_shptr->get_allocator(); }
			typename _MV::const_reference at(size_type _Pos) const { return m_shptr->at(_Pos); }
			typename _MV::reference at(size_type _Pos) { return m_shptr->at(_Pos); }
			typename _MV::reference front() { return m_shptr->front(); }
			typename _MV::const_reference front() const { return m_shptr->front(); }
			typename _MV::reference back() { return m_shptr->back(); }
			typename _MV::const_reference back() const { return m_shptr->back(); }

			/* Try to avoid using these whenever possible. */
			value_type *data() _NOEXCEPT {
				return m_shptr->data();
			}
			const value_type *data() const _NOEXCEPT {
				return m_shptr->data();
			}


			class const_iterator : public _MV::random_access_const_iterator_base {
			public:
				typedef typename _MV::ss_const_iterator_type::iterator_category iterator_category;
				typedef typename _MV::ss_const_iterator_type::value_type value_type;
				typedef typename _MV::ss_const_iterator_type::difference_type difference_type;
				typedef typename _MV::difference_type distance_type;	// retained
				typedef typename _MV::ss_const_iterator_type::pointer pointer;
				typedef typename _MV::ss_const_iterator_type::reference reference;

				const_iterator() {}
				const_iterator(const const_iterator& src_cref) : m_msevector_cshptr(src_cref.m_msevector_cshptr) {
					(*this) = src_cref;
				}
				~const_iterator() {}
				const typename _MV::ss_const_iterator_type& msevector_ss_const_iterator_type() const { return m_ss_const_iterator; }
				typename _MV::ss_const_iterator_type& msevector_ss_const_iterator_type() { return m_ss_const_iterator; }
				const typename _MV::ss_const_iterator_type& mvssci() const { return msevector_ss_const_iterator_type(); }
				typename _MV::ss_const_iterator_type& mvssci() { return msevector_ss_const_iterator_type(); }

				void reset() { msevector_ss_const_iterator_type().reset(); }
				bool points_to_an_item() const { return msevector_ss_const_iterator_type().points_to_an_item(); }
				bool points_to_end_marker() const { return msevector_ss_const_iterator_type().points_to_end_marker(); }
				bool points_to_beginning() const { return msevector_ss_const_iterator_type().points_to_beginning(); }
				/* has_next_item_or_end_marker() is just an alias for points_to_an_item(). */
				bool has_next_item_or_end_marker() const { return msevector_ss_const_iterator_type().has_next_item_or_end_marker(); }
				/* has_next() is just an alias for points_to_an_item() that's familiar to java programmers. */
				bool has_next() const { return msevector_ss_const_iterator_type().has_next(); }
				bool has_previous() const { return msevector_ss_const_iterator_type().has_previous(); }
				void set_to_beginning() { msevector_ss_const_iterator_type().set_to_beginning(); }
				void set_to_end_marker() { msevector_ss_const_iterator_type().set_to_end_marker(); }
				void set_to_next() { msevector_ss_const_iterator_type().set_to_next(); }
				void set_to_previous() { msevector_ss_const_iterator_type().set_to_previous(); }
				const_iterator& operator ++() { msevector_ss_const_iterator_type().operator ++(); return (*this); }
				const_iterator operator++(int) { const_iterator _Tmp = *this; ++*this; return (_Tmp); }
				const_iterator& operator --() { msevector_ss_const_iterator_type().operator --(); return (*this); }
				const_iterator operator--(int) { const_iterator _Tmp = *this; --*this; return (_Tmp); }
				void advance(typename _MV::difference_type n) { msevector_ss_const_iterator_type().advance(n); }
				void regress(typename _MV::difference_type n) { msevector_ss_const_iterator_type().regress(n); }
				const_iterator& operator +=(difference_type n) { msevector_ss_const_iterator_type().operator +=(n); return (*this); }
				const_iterator& operator -=(difference_type n) { msevector_ss_const_iterator_type().operator -=(n); return (*this); }
				const_iterator operator+(difference_type n) const { auto retval = (*this); retval += n; return retval; }
				const_iterator operator-(difference_type n) const { return ((*this) + (-n)); }
				typename _MV::difference_type operator-(const const_iterator& _Right_cref) const { return msevector_ss_const_iterator_type() - (_Right_cref.msevector_ss_const_iterator_type()); }
				typename _MV::const_reference operator*() const { return msevector_ss_const_iterator_type().operator*(); }
				typename _MV::const_reference item() const { return operator*(); }
				typename _MV::const_reference previous_item() const { return msevector_ss_const_iterator_type().previous_item(); }
				typename _MV::const_pointer operator->() const { return msevector_ss_const_iterator_type().operator->(); }
				typename _MV::const_reference operator[](typename _MV::difference_type _Off) const { return (*(*this + _Off)); }
				bool operator==(const const_iterator& _Right_cref) const { return msevector_ss_const_iterator_type().operator==(_Right_cref.msevector_ss_const_iterator_type()); }
				bool operator!=(const const_iterator& _Right_cref) const { return (!(_Right_cref == (*this))); }
				bool operator<(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() < _Right.msevector_ss_const_iterator_type()); }
				bool operator<=(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() <= _Right.msevector_ss_const_iterator_type()); }
				bool operator>(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() > _Right.msevector_ss_const_iterator_type()); }
				bool operator>=(const const_iterator& _Right) const { return (msevector_ss_const_iterator_type() >= _Right.msevector_ss_const_iterator_type()); }
				void set_to_const_item_pointer(const const_iterator& _Right_cref) { msevector_ss_const_iterator_type().set_to_const_item_pointer(_Right_cref.msevector_ss_const_iterator_type()); }
				msev_size_t position() const { return msevector_ss_const_iterator_type().position(); }
			private:
				const_iterator(std::shared_ptr<_MV> msevector_shptr) : m_msevector_cshptr(msevector_shptr) {
					m_ss_const_iterator = msevector_shptr->ss_cbegin();
				}
				std::shared_ptr<const _MV> m_msevector_cshptr;
				/* m_ss_const_iterator needs to be declared after m_msevector_cshptr so that it's destructor will be called first. */
				typename _MV::ss_const_iterator_type m_ss_const_iterator;
				friend class /*_Myt*/vector<_Ty, _A>;
				friend class iterator;
			};
			class iterator : public _MV::random_access_iterator_base {
			public:
				typedef typename _MV::ss_iterator_type::iterator_category iterator_category;
				typedef typename _MV::ss_iterator_type::value_type value_type;
				typedef typename _MV::ss_iterator_type::difference_type difference_type;
				typedef typename _MV::difference_type distance_type;	// retained
				typedef typename _MV::ss_iterator_type::pointer pointer;
				typedef typename _MV::ss_iterator_type::reference reference;

				iterator() {}
				iterator(const iterator& src_cref) : m_msevector_shptr(src_cref.m_msevector_shptr) {
					(*this) = src_cref;
				}
				~iterator() {}
				const typename _MV::ss_iterator_type& msevector_ss_iterator_type() const { return m_ss_iterator; }
				typename _MV::ss_iterator_type& msevector_ss_iterator_type() { return m_ss_iterator; }
				const typename _MV::ss_iterator_type& mvssi() const { return msevector_ss_iterator_type(); }
				typename _MV::ss_iterator_type& mvssi() { return msevector_ss_iterator_type(); }
				operator const_iterator() const {
					const_iterator retval(m_msevector_shptr);
					if (m_msevector_shptr) {
						retval.msevector_ss_const_iterator_type().set_to_beginning();
						retval.msevector_ss_const_iterator_type().advance(msev_int(msevector_ss_iterator_type().position()));
					}
					return retval;
				}

				void reset() { msevector_ss_iterator_type().reset(); }
				bool points_to_an_item() const { return msevector_ss_iterator_type().points_to_an_item(); }
				bool points_to_end_marker() const { return msevector_ss_iterator_type().points_to_end_marker(); }
				bool points_to_beginning() const { return msevector_ss_iterator_type().points_to_beginning(); }
				/* has_next_item_or_end_marker() is just an alias for points_to_an_item(). */
				bool has_next_item_or_end_marker() const { return msevector_ss_iterator_type().has_next_item_or_end_marker(); }
				/* has_next() is just an alias for points_to_an_item() that's familiar to java programmers. */
				bool has_next() const { return msevector_ss_iterator_type().has_next(); }
				bool has_previous() const { return msevector_ss_iterator_type().has_previous(); }
				void set_to_beginning() { msevector_ss_iterator_type().set_to_beginning(); }
				void set_to_end_marker() { msevector_ss_iterator_type().set_to_end_marker(); }
				void set_to_next() { msevector_ss_iterator_type().set_to_next(); }
				void set_to_previous() { msevector_ss_iterator_type().set_to_previous(); }
				iterator& operator ++() { msevector_ss_iterator_type().operator ++(); return (*this); }
				iterator operator++(int) { iterator _Tmp = *this; ++*this; return (_Tmp); }
				iterator& operator --() { msevector_ss_iterator_type().operator --(); return (*this); }
				iterator operator--(int) { iterator _Tmp = *this; --*this; return (_Tmp); }
				void advance(typename _MV::difference_type n) { msevector_ss_iterator_type().advance(n); }
				void regress(typename _MV::difference_type n) { msevector_ss_iterator_type().regress(n); }
				iterator& operator +=(difference_type n) { msevector_ss_iterator_type().operator +=(n); return (*this); }
				iterator& operator -=(difference_type n) { msevector_ss_iterator_type().operator -=(n); return (*this); }
				iterator operator+(difference_type n) const { auto retval = (*this); retval += n; return retval; }
				iterator operator-(difference_type n) const { return ((*this) + (-n)); }
				typename _MV::difference_type operator-(const iterator& _Right_cref) const { return msevector_ss_iterator_type() - (_Right_cref.msevector_ss_iterator_type()); }
				typename _MV::reference operator*() const { return msevector_ss_iterator_type().operator*(); }
				typename _MV::reference item() const { return operator*(); }
				typename _MV::reference previous_item() const { return msevector_ss_iterator_type().previous_item(); }
				typename _MV::pointer operator->() const { return msevector_ss_iterator_type().operator->(); }
				typename _MV::reference operator[](typename _MV::difference_type _Off) const { return (*(*this + _Off)); }
				bool operator==(const iterator& _Right_cref) const { return msevector_ss_iterator_type().operator==(_Right_cref.msevector_ss_iterator_type()); }
				bool operator!=(const iterator& _Right_cref) const { return (!(_Right_cref == (*this))); }
				bool operator<(const iterator& _Right) const { return (msevector_ss_iterator_type() < _Right.msevector_ss_iterator_type()); }
				bool operator<=(const iterator& _Right) const { return (msevector_ss_iterator_type() <= _Right.msevector_ss_iterator_type()); }
				bool operator>(const iterator& _Right) const { return (msevector_ss_iterator_type() > _Right.msevector_ss_iterator_type()); }
				bool operator>=(const iterator& _Right) const { return (msevector_ss_iterator_type() >= _Right.msevector_ss_iterator_type()); }
				void set_to_item_pointer(const iterator& _Right_cref) { msevector_ss_iterator_type().set_to_item_pointer(_Right_cref.msevector_ss_iterator_type()); }
				msev_size_t position() const { return msevector_ss_iterator_type().position(); }
			private:
				std::shared_ptr<_MV> m_msevector_shptr;
				/* m_ss_iterator needs to be declared after m_msevector_shptr so that it's destructor will be called first. */
				typename _MV::ss_iterator_type m_ss_iterator;
				friend class /*_Myt*/vector<_Ty, _A>;
			};

			iterator begin() {	// return iterator for beginning of mutable sequence
				iterator retval; retval.m_msevector_shptr = this->m_shptr;
				(retval.m_ss_iterator) = m_shptr->ss_begin();
				return retval;
			}
			const_iterator begin() const {	// return iterator for beginning of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_begin();
				return retval;
			}
			iterator end() {	// return iterator for end of mutable sequence
				iterator retval; retval.m_msevector_shptr = this->m_shptr;
				(retval.m_ss_iterator) = m_shptr->ss_end();
				return retval;
			}
			const_iterator end() const {	// return iterator for end of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_end();
				return retval;
			}
			const_iterator cbegin() const {	// return iterator for beginning of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_cbegin();
				return retval;
			}
			const_iterator cend() const {	// return iterator for end of nonmutable sequence
				const_iterator retval; retval.m_msevector_cshptr = this->m_shptr;
				(retval.m_ss_const_iterator) = m_shptr->ss_cend();
				return retval;
			}

			typedef std::reverse_iterator<iterator> reverse_iterator;
			typedef std::reverse_iterator<const_iterator> const_reverse_iterator;

			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()));
			}
			const_reverse_iterator crbegin() const {	// return iterator for beginning of reversed nonmutable sequence
				return (rbegin());
			}
			const_reverse_iterator crend() const {	// return iterator for end of reversed nonmutable sequence
				return (rend());
			}


			vector(const const_iterator &start, const const_iterator &end, const _A& _Al = _A())
				: m_shptr(std::make_shared<_MV>(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type(), _Al)) {}
			void assign(const const_iterator &start, const const_iterator &end) {
				m_shptr->assign(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type());
			}
			void assign_inclusive(const const_iterator &first, const const_iterator &last) {
				m_shptr->assign_inclusive(first.msevector_ss_const_iterator_type(), last.msevector_ss_const_iterator_type());
			}
			iterator insert_before(const const_iterator &pos, size_type _M, const _Ty& _X) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), _M, _X);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator insert_before(const const_iterator &pos, _Ty&& _X) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), std::move(_X));
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator insert_before(const const_iterator &pos, const _Ty& _X = _Ty()) { return insert_before(pos, 1, _X); }
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert_before(const const_iterator &pos, const _Iter &start, const _Iter &end) {
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), start, end);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert_before_inclusive(const const_iterator &pos, const _Iter &first, const _Iter &last) {
				auto end = last; end++;
				return insert_before(pos, first, end);
			}
			iterator insert_before(const const_iterator &pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) {	// insert initializer_list
				auto res = m_shptr->insert_before(pos.msevector_ss_const_iterator_type(), _Ilist);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			void insert_before(msev_size_t pos, const _Ty& _X = _Ty()) {
				m_shptr->insert_before(pos, _X);
			}
			void insert_before(msev_size_t pos, size_type _M, const _Ty& _X) {
				m_shptr->insert_before(pos, _M, _X);
			}
			void insert_before(msev_size_t pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) {	// insert initializer_list
				m_shptr->insert_before(pos, _Ilist);
			}
			/* These insert() functions are just aliases for their corresponding insert_before() functions. */
			iterator insert(const const_iterator &pos, size_type _M, const _Ty& _X) { return insert_before(pos, _M, _X); }
			iterator insert(const const_iterator &pos, _Ty&& _X) { return insert_before(pos, std::move(_X)); }
			iterator insert(const const_iterator &pos, const _Ty& _X = _Ty()) { return insert_before(pos, _X); }
			template<class _Iter
				//>typename std::enable_if<_mse_Is_iterator<_Iter>::value, typename base_class::iterator>::type
				, class = _mse_RequireInputIter<_Iter> >
			iterator insert(const const_iterator &pos, const _Iter &start, const _Iter &end) { return insert_before(pos, start, end); }
			iterator insert(const const_iterator &pos, const _Ty* start, const _Ty* end) { return insert_before(pos, start, end); }
			iterator insert(const const_iterator &pos, _XSTD initializer_list<typename _MV::value_type> _Ilist) { return insert_before(pos, _Ilist); }
			template<class ..._Valty>
			iterator emplace(const const_iterator &pos, _Valty&& ..._Val) {
				auto res = m_shptr->emplace(pos.msevector_ss_const_iterator_type(), std::forward<_Valty>(_Val)...);
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase(const const_iterator &pos) {
				auto res = m_shptr->erase(pos.msevector_ss_const_iterator_type());
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase(const const_iterator &start, const const_iterator &end) {
				auto res = m_shptr->erase(start.msevector_ss_const_iterator_type(), end.msevector_ss_const_iterator_type());
				iterator retval = begin(); retval.msevector_ss_iterator_type() = res;
				return retval;
			}
			iterator erase_inclusive(const const_iterator &first, const const_iterator &last) {
				auto end = last; end.set_to_next();
				return erase_inclusive(first, end);
			}
			bool operator==(const _Myt& _Right) const {	// test for vector equality
				return ((*(_Right.m_shptr)) == (*m_shptr));
			}
			bool operator<(const _Myt& _Right) const {	// test if _Left < _Right for vectors
				return ((*m_shptr) < (*(_Right.m_shptr)));
			}

		private:
			std::shared_ptr<_MV> m_shptr;
		};

		template<class _Ty, class _Alloc> inline bool operator!=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test for vector inequality
			return (!(_Left == _Right));
		}

		template<class _Ty, class _Alloc> inline bool operator>(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left > _Right for vectors
			return (_Right < _Left);
		}

		template<class _Ty, class _Alloc> inline bool operator<=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left <= _Right for vectors
			return (!(_Right < _Left));
		}

		template<class _Ty, class _Alloc> inline bool operator>=(const vector<_Ty, _Alloc>& _Left,
			const vector<_Ty, _Alloc>& _Right) {	// test if _Left >= _Right for vectors
			return (!(_Left < _Right));
		}
#endif /*MSE_MSTDVECTOR_DISABLED*/
	}
}
#endif /*ndef MSEMSTDVECTOR_H*/