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// Boost.Container varray
//
// Copyright (c) 2012-2013 Adam Wulkiewicz, Lodz, Poland.
// Copyright (c) 2011-2013 Andrew Hundt.
// Copyright (c) 2014-2014 Ion Gaztanaga
//
// 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 BOOST_CONTAINER_VARRAY_HPP
#define BOOST_CONTAINER_VARRAY_HPP
#ifndef BOOST_CONFIG_HPP
# include <boost/config.hpp>
#endif
#if defined(BOOST_HAS_PRAGMA_ONCE)
# pragma once
#endif
#include <boost/container/detail/config_begin.hpp>
#include "detail/varray.hpp"
#include <boost/move/utility_core.hpp>
namespace boost { namespace container {
/**
* @defgroup varray_non_member varray non-member functions
*/
/**
* @brief A variable-size array container with fixed capacity.
*
* varray is a sequence container like boost::container::vector with contiguous storage that can
* change in size, along with the static allocation, low overhead, and fixed capacity of boost::array.
*
* A varray is a sequence that supports random access to elements, constant time insertion and
* removal of elements at the end, and linear time insertion and removal of elements at the beginning or
* in the middle. The number of elements in a varray may vary dynamically up to a fixed capacity
* because elements are stored within the object itself similarly to an array. However, objects are
* initialized as they are inserted into varray unlike C arrays or std::array which must construct
* all elements on instantiation. The behavior of varray enables the use of statically allocated
* elements in cases with complex object lifetime requirements that would otherwise not be trivially
* possible.
*
* @par Error Handling
* Insertion beyond the capacity and out of bounds errors result in undefined behavior.
* The reason for this is because unlike vectors, varray does not perform allocation.
*
* @tparam Value The type of element that will be stored.
* @tparam Capacity The maximum number of elements varray can store, fixed at compile time.
*/
template <typename Value, std::size_t Capacity>
class varray
: public dtl::varray<Value, Capacity>
{
typedef dtl::varray<Value, Capacity> base_t;
BOOST_COPYABLE_AND_MOVABLE(varray)
public:
//! @brief The type of elements stored in the container.
typedef typename base_t::value_type value_type;
//! @brief The unsigned integral type used by the container.
typedef typename base_t::size_type size_type;
//! @brief The pointers difference type.
typedef typename base_t::difference_type difference_type;
//! @brief The pointer type.
typedef typename base_t::pointer pointer;
//! @brief The const pointer type.
typedef typename base_t::const_pointer const_pointer;
//! @brief The value reference type.
typedef typename base_t::reference reference;
//! @brief The value const reference type.
typedef typename base_t::const_reference const_reference;
//! @brief The iterator type.
typedef typename base_t::iterator iterator;
//! @brief The const iterator type.
typedef typename base_t::const_iterator const_iterator;
//! @brief The reverse iterator type.
typedef typename base_t::reverse_iterator reverse_iterator;
//! @brief The const reverse iterator.
typedef typename base_t::const_reverse_iterator const_reverse_iterator;
//! @brief Constructs an empty varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
varray()
: base_t()
{}
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief Constructs a varray containing count value initialized Values.
//!
//! @param count The number of values which will be contained in the container.
//!
//! @par Throws
//! If Value's value initialization throws.
//!
//! @par Complexity
//! Linear O(N).
explicit varray(size_type count)
: base_t(count)
{}
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief Constructs a varray containing count copies of value.
//!
//! @param count The number of copies of a values that will be contained in the container.
//! @param value The value which will be used to copy construct values.
//!
//! @par Throws
//! If Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
varray(size_type count, value_type const& value)
: base_t(count, value)
{}
//! @pre
//! @li <tt>distance(first, last) <= capacity()</tt>
//! @li Iterator must meet the \c ForwardTraversalIterator concept.
//!
//! @brief Constructs a varray containing copy of a range <tt>[first, last)</tt>.
//!
//! @param first The iterator to the first element in range.
//! @param last The iterator to the one after the last element in range.
//!
//! @par Throws
//! If Value's constructor taking a dereferenced Iterator throws.
//!
//! @par Complexity
//! Linear O(N).
template <typename Iterator>
varray(Iterator first, Iterator last)
: base_t(first, last)
{}
//! @brief Constructs a copy of other varray.
//!
//! @param other The varray which content will be copied to this one.
//!
//! @par Throws
//! If Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
varray(varray const& other)
: base_t(other)
{}
//! @pre <tt>other.size() <= capacity()</tt>.
//!
//! @brief Constructs a copy of other varray.
//!
//! @param other The varray which content will be copied to this one.
//!
//! @par Throws
//! If Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
template <std::size_t C>
varray(varray<value_type, C> const& other) : base_t(other) {}
//! @brief Copy assigns Values stored in the other varray to this one.
//!
//! @param other The varray which content will be copied to this one.
//!
//! @par Throws
//! If Value's copy constructor or copy assignment throws.
//!
//! @par Complexity
//! Linear O(N).
varray & operator=(BOOST_COPY_ASSIGN_REF(varray) other)
{
base_t::operator=(static_cast<base_t const&>(other));
return *this;
}
//! @pre <tt>other.size() <= capacity()</tt>
//!
//! @brief Copy assigns Values stored in the other varray to this one.
//!
//! @param other The varray which content will be copied to this one.
//!
//! @par Throws
//! If Value's copy constructor or copy assignment throws.
//!
//! @par Complexity
//! Linear O(N).
template <std::size_t C>
// TEMPORARY WORKAROUND
#if defined(BOOST_NO_CXX11_RVALUE_REFERENCES)
varray & operator=(::boost::rv< varray<value_type, C> > const& other)
#else
varray & operator=(varray<value_type, C> const& other)
#endif
{
base_t::operator=(static_cast<varray<value_type, C> const&>(other));
return *this;
}
//! @brief Move constructor. Moves Values stored in the other varray to this one.
//!
//! @param other The varray which content will be moved to this one.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor throws.
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
varray(BOOST_RV_REF(varray) other)
: base_t(boost::move(static_cast<base_t&>(other)))
{}
//! @pre <tt>other.size() <= capacity()</tt>
//!
//! @brief Move constructor. Moves Values stored in the other varray to this one.
//!
//! @param other The varray which content will be moved to this one.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor throws.
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
template <std::size_t C>
varray(BOOST_RV_REF_2_TEMPL_ARGS(varray, value_type, C) other)
: base_t(boost::move(static_cast<dtl::varray<value_type, C>&>(other)))
{}
//! @brief Move assignment. Moves Values stored in the other varray to this one.
//!
//! @param other The varray which content will be moved to this one.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor or move assignment throws.
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor or copy assignment throws.
//!
//! @par Complexity
//! Linear O(N).
varray & operator=(BOOST_RV_REF(varray) other)
{
base_t::operator=(boost::move(static_cast<base_t&>(other)));
return *this;
}
//! @pre <tt>other.size() <= capacity()</tt>
//!
//! @brief Move assignment. Moves Values stored in the other varray to this one.
//!
//! @param other The varray which content will be moved to this one.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor or move assignment throws.
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor or copy assignment throws.
//!
//! @par Complexity
//! Linear O(N).
template <std::size_t C>
varray & operator=(BOOST_RV_REF_2_TEMPL_ARGS(varray, value_type, C) other)
{
base_t::operator=(boost::move(static_cast<dtl::varray<value_type, C>&>(other)));
return *this;
}
#ifdef BOOST_CONTAINER_DOXYGEN_INVOKED
//! @brief Destructor. Destroys Values stored in this container.
//!
//! @par Throws
//! Nothing
//!
//! @par Complexity
//! Linear O(N).
~varray();
//! @brief Swaps contents of the other varray and this one.
//!
//! @param other The varray which content will be swapped with this one's content.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor or move assignment throws,
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor or copy assignment throws,
//!
//! @par Complexity
//! Linear O(N).
void swap(varray & other);
//! @pre <tt>other.size() <= capacity() && size() <= other.capacity()</tt>
//!
//! @brief Swaps contents of the other varray and this one.
//!
//! @param other The varray which content will be swapped with this one's content.
//!
//! @par Throws
//! @li If \c boost::has_nothrow_move<Value>::value is \c true and Value's move constructor or move assignment throws,
//! @li If \c boost::has_nothrow_move<Value>::value is \c false and Value's copy constructor or copy assignment throws,
//!
//! @par Complexity
//! Linear O(N).
template <std::size_t C>
void swap(varray<value_type, C> & other);
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief Inserts or erases elements at the end such that
//! the size becomes count. New elements are value initialized.
//!
//! @param count The number of elements which will be stored in the container.
//!
//! @par Throws
//! If Value's value initialization throws.
//!
//! @par Complexity
//! Linear O(N).
void resize(size_type count);
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief Inserts or erases elements at the end such that
//! the size becomes count. New elements are copy constructed from value.
//!
//! @param count The number of elements which will be stored in the container.
//! @param value The value used to copy construct the new element.
//!
//! @par Throws
//! If Value's copy constructor throws.
//!
//! @par Complexity
//! Linear O(N).
void resize(size_type count, value_type const& value);
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief This call has no effect because the Capacity of this container is constant.
//!
//! @param count The number of elements which the container should be able to contain.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Linear O(N).
void reserve(size_type count);
//! @pre <tt>size() < capacity()</tt>
//!
//! @brief Adds a copy of value at the end.
//!
//! @param value The value used to copy construct the new element.
//!
//! @par Throws
//! If Value's copy constructor throws.
//!
//! @par Complexity
//! Constant O(1).
void push_back(value_type const& value);
//! @pre <tt>size() < capacity()</tt>
//!
//! @brief Moves value to the end.
//!
//! @param value The value to move construct the new element.
//!
//! @par Throws
//! If Value's move constructor throws.
//!
//! @par Complexity
//! Constant O(1).
void push_back(BOOST_RV_REF(value_type) value);
//! @pre <tt>!empty()</tt>
//!
//! @brief Destroys last value and decreases the size.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
void pop_back();
//! @pre
//! @li \c position must be a valid iterator of \c *this in range <tt>[begin(), end()]</tt>.
//! @li <tt>size() < capacity()</tt>
//!
//! @brief Inserts a copy of element at position.
//!
//! @param position The position at which the new value will be inserted.
//! @param value The value used to copy construct the new element.
//!
//! @par Throws
//! @li If Value's copy constructor or copy assignment throws
//! @li If Value's move constructor or move assignment throws.
//!
//! @par Complexity
//! Constant or linear.
iterator insert(iterator position, value_type const& value);
//! @pre
//! @li \c position must be a valid iterator of \c *this in range <tt>[begin(), end()]</tt>.
//! @li <tt>size() < capacity()</tt>
//!
//! @brief Inserts a move-constructed element at position.
//!
//! @param position The position at which the new value will be inserted.
//! @param value The value used to move construct the new element.
//!
//! @par Throws
//! If Value's move constructor or move assignment throws.
//!
//! @par Complexity
//! Constant or linear.
iterator insert(iterator position, BOOST_RV_REF(value_type) value);
//! @pre
//! @li \c position must be a valid iterator of \c *this in range <tt>[begin(), end()]</tt>.
//! @li <tt>size() + count <= capacity()</tt>
//!
//! @brief Inserts a count copies of value at position.
//!
//! @param position The position at which new elements will be inserted.
//! @param count The number of new elements which will be inserted.
//! @param value The value used to copy construct new elements.
//!
//! @par Throws
//! @li If Value's copy constructor or copy assignment throws.
//! @li If Value's move constructor or move assignment throws.
//!
//! @par Complexity
//! Linear O(N).
iterator insert(iterator position, size_type count, value_type const& value);
//! @pre
//! @li \c position must be a valid iterator of \c *this in range <tt>[begin(), end()]</tt>.
//! @li <tt>distance(first, last) <= capacity()</tt>
//! @li \c Iterator must meet the \c ForwardTraversalIterator concept.
//!
//! @brief Inserts a copy of a range <tt>[first, last)</tt> at position.
//!
//! @param position The position at which new elements will be inserted.
//! @param first The iterator to the first element of a range used to construct new elements.
//! @param last The iterator to the one after the last element of a range used to construct new elements.
//!
//! @par Throws
//! @li If Value's constructor and assignment taking a dereferenced \c Iterator.
//! @li If Value's move constructor or move assignment throws.
//!
//! @par Complexity
//! Linear O(N).
template <typename Iterator>
iterator insert(iterator position, Iterator first, Iterator last);
//! @pre \c position must be a valid iterator of \c *this in range <tt>[begin(), end())</tt>
//!
//! @brief Erases Value from position.
//!
//! @param position The position of the element which will be erased from the container.
//!
//! @par Throws
//! If Value's move assignment throws.
//!
//! @par Complexity
//! Linear O(N).
iterator erase(iterator position);
//! @pre
//! @li \c first and \c last must define a valid range
//! @li iterators must be in range <tt>[begin(), end()]</tt>
//!
//! @brief Erases Values from a range <tt>[first, last)</tt>.
//!
//! @param first The position of the first element of a range which will be erased from the container.
//! @param last The position of the one after the last element of a range which will be erased from the container.
//!
//! @par Throws
//! If Value's move assignment throws.
//!
//! @par Complexity
//! Linear O(N).
iterator erase(iterator first, iterator last);
//! @pre <tt>distance(first, last) <= capacity()</tt>
//!
//! @brief Assigns a range <tt>[first, last)</tt> of Values to this container.
//!
//! @param first The iterator to the first element of a range used to construct new content of this container.
//! @param last The iterator to the one after the last element of a range used to construct new content of this container.
//!
//! @par Throws
//! If Value's copy constructor or copy assignment throws,
//!
//! @par Complexity
//! Linear O(N).
template <typename Iterator>
void assign(Iterator first, Iterator last);
//! @pre <tt>count <= capacity()</tt>
//!
//! @brief Assigns a count copies of value to this container.
//!
//! @param count The new number of elements which will be container in the container.
//! @param value The value which will be used to copy construct the new content.
//!
//! @par Throws
//! If Value's copy constructor or copy assignment throws.
//!
//! @par Complexity
//! Linear O(N).
void assign(size_type count, value_type const& value);
//! @pre <tt>size() < capacity()</tt>
//!
//! @brief Inserts a Value constructed with
//! \c std::forward<Args>(args)... in the end of the container.
//!
//! @param args The arguments of the constructor of the new element which will be created at the end of the container.
//!
//! @par Throws
//! If in-place constructor throws or Value's move constructor throws.
//!
//! @par Complexity
//! Constant O(1).
template<class ...Args>
void emplace_back(Args &&...args);
//! @pre
//! @li \c position must be a valid iterator of \c *this in range <tt>[begin(), end()]</tt>
//! @li <tt>size() < capacity()</tt>
//!
//! @brief Inserts a Value constructed with
//! \c std::forward<Args>(args)... before position
//!
//! @param position The position at which new elements will be inserted.
//! @param args The arguments of the constructor of the new element.
//!
//! @par Throws
//! If in-place constructor throws or if Value's move constructor or move assignment throws.
//!
//! @par Complexity
//! Constant or linear.
template<class ...Args>
iterator emplace(iterator position, Args &&...args);
//! @brief Removes all elements from the container.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
void clear();
//! @pre <tt>i < size()</tt>
//!
//! @brief Returns reference to the i-th element.
//!
//! @param i The element's index.
//!
//! @return reference to the i-th element
//! from the beginning of the container.
//!
//! @par Throws
//! \c std::out_of_range exception by default.
//!
//! @par Complexity
//! Constant O(1).
reference at(size_type i);
//! @pre <tt>i < size()</tt>
//!
//! @brief Returns const reference to the i-th element.
//!
//! @param i The element's index.
//!
//! @return const reference to the i-th element
//! from the beginning of the container.
//!
//! @par Throws
//! \c std::out_of_range exception by default.
//!
//! @par Complexity
//! Constant O(1).
const_reference at(size_type i) const;
//! @pre <tt>i < size()</tt>
//!
//! @brief Returns reference to the i-th element.
//!
//! @param i The element's index.
//!
//! @return reference to the i-th element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
reference operator[](size_type i);
//! @pre <tt>i < size()</tt>
//!
//! @brief Returns const reference to the i-th element.
//!
//! @param i The element's index.
//!
//! @return const reference to the i-th element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
const_reference operator[](size_type i) const;
//! @pre \c !empty()
//!
//! @brief Returns reference to the first element.
//!
//! @return reference to the first element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
reference front();
//! @pre \c !empty()
//!
//! @brief Returns const reference to the first element.
//!
//! @return const reference to the first element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
const_reference front() const;
//! @pre \c !empty()
//!
//! @brief Returns reference to the last element.
//!
//! @return reference to the last element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
reference back();
//! @pre \c !empty()
//!
//! @brief Returns const reference to the first element.
//!
//! @return const reference to the last element
//! from the beginning of the container.
//!
//! @par Throws
//! Nothing by default.
//!
//! @par Complexity
//! Constant O(1).
const_reference back() const;
//! @brief Pointer such that <tt>[data(), data() + size())</tt> is a valid range.
//! For a non-empty vector <tt>data() == &front()</tt>.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
Value * data();
//! @brief Const pointer such that <tt>[data(), data() + size())</tt> is a valid range.
//! For a non-empty vector <tt>data() == &front()</tt>.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const Value * data() const;
//! @brief Returns iterator to the first element.
//!
//! @return iterator to the first element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
iterator begin();
//! @brief Returns const iterator to the first element.
//!
//! @return const_iterator to the first element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_iterator begin() const;
//! @brief Returns const iterator to the first element.
//!
//! @return const_iterator to the first element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_iterator cbegin() const;
//! @brief Returns iterator to the one after the last element.
//!
//! @return iterator pointing to the one after the last element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
iterator end();
//! @brief Returns const iterator to the one after the last element.
//!
//! @return const_iterator pointing to the one after the last element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_iterator end() const;
//! @brief Returns const iterator to the one after the last element.
//!
//! @return const_iterator pointing to the one after the last element contained in the vector.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_iterator cend() const;
//! @brief Returns reverse iterator to the first element of the reversed container.
//!
//! @return reverse_iterator pointing to the beginning
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
reverse_iterator rbegin();
//! @brief Returns const reverse iterator to the first element of the reversed container.
//!
//! @return const_reverse_iterator pointing to the beginning
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_reverse_iterator rbegin() const;
//! @brief Returns const reverse iterator to the first element of the reversed container.
//!
//! @return const_reverse_iterator pointing to the beginning
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_reverse_iterator crbegin() const;
//! @brief Returns reverse iterator to the one after the last element of the reversed container.
//!
//! @return reverse_iterator pointing to the one after the last element
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
reverse_iterator rend();
//! @brief Returns const reverse iterator to the one after the last element of the reversed container.
//!
//! @return const_reverse_iterator pointing to the one after the last element
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_reverse_iterator rend() const;
//! @brief Returns const reverse iterator to the one after the last element of the reversed container.
//!
//! @return const_reverse_iterator pointing to the one after the last element
//! of the reversed varray.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
const_reverse_iterator crend() const;
//! @brief Returns container's capacity.
//!
//! @return container's capacity.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
static size_type capacity();
//! @brief Returns container's capacity.
//!
//! @return container's capacity.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
static size_type max_size();
//! @brief Returns the number of stored elements.
//!
//! @return Number of elements contained in the container.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
size_type size() const;
//! @brief Queries if the container contains elements.
//!
//! @return true if the number of elements contained in the
//! container is equal to 0.
//!
//! @par Throws
//! Nothing.
//!
//! @par Complexity
//! Constant O(1).
bool empty() const;
#endif // BOOST_CONTAINER_DOXYGEN_INVOKED
};
#ifdef BOOST_CONTAINER_DOXYGEN_INVOKED
//! @brief Checks if contents of two varrays are equal.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if containers have the same size and elements in both containers are equal.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator== (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Checks if contents of two varrays are not equal.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if containers have different size or elements in both containers are not equal.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator!= (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Lexicographically compares varrays.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if x compares lexicographically less than y.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator< (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Lexicographically compares varrays.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if y compares lexicographically less than x.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator> (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Lexicographically compares varrays.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if y don't compare lexicographically less than x.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator<= (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Lexicographically compares varrays.
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @return \c true if x don't compare lexicographically less than y.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
bool operator>= (varray<V, C1> const& x, varray<V, C2> const& y);
//! @brief Swaps contents of two varrays.
//!
//! This function calls varray::swap().
//!
//! @ingroup varray_non_member
//!
//! @param x The first varray.
//! @param y The second varray.
//!
//! @par Complexity
//! Linear O(N).
template<typename V, std::size_t C1, std::size_t C2>
inline void swap(varray<V, C1> & x, varray<V, C2> & y);
#endif // BOOST_CONTAINER_DOXYGEN_INVOKED
}} // namespace boost::container
#include <boost/container/detail/config_end.hpp>
#endif // BOOST_CONTAINER_VARRAY_HPP