1426 lines
78 KiB
C++
1426 lines
78 KiB
C++
// Implementation of the circular buffer adaptor.
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// Copyright (c) 2003-2008 Jan Gaspar
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// Use, modification, and distribution is subject to the Boost Software
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// License, Version 1.0. (See accompanying file LICENSE_1_0.txt or copy at
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// http://www.boost.org/LICENSE_1_0.txt)
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#if !defined(BOOST_CIRCULAR_BUFFER_SPACE_OPTIMIZED_HPP)
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#define BOOST_CIRCULAR_BUFFER_SPACE_OPTIMIZED_HPP
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#if defined(_MSC_VER) && _MSC_VER >= 1200
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#pragma once
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#endif
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#include <boost/type_traits/is_same.hpp>
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#include <boost/detail/workaround.hpp>
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namespace boost {
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/*!
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\class circular_buffer_space_optimized
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\brief Space optimized circular buffer container adaptor.
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For detailed documentation of the space_optimized_circular_buffer visit:
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http://www.boost.org/libs/circular_buffer/doc/space_optimized.html
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*/
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template <class T, class Alloc>
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class circular_buffer_space_optimized :
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/*! \cond */
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#if BOOST_CB_ENABLE_DEBUG
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public
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#endif
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/*! \endcond */
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circular_buffer<T, Alloc> {
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public:
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// Typedefs
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typedef typename circular_buffer<T, Alloc>::value_type value_type;
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typedef typename circular_buffer<T, Alloc>::pointer pointer;
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typedef typename circular_buffer<T, Alloc>::const_pointer const_pointer;
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typedef typename circular_buffer<T, Alloc>::reference reference;
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typedef typename circular_buffer<T, Alloc>::const_reference const_reference;
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typedef typename circular_buffer<T, Alloc>::size_type size_type;
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typedef typename circular_buffer<T, Alloc>::difference_type difference_type;
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typedef typename circular_buffer<T, Alloc>::allocator_type allocator_type;
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typedef typename circular_buffer<T, Alloc>::const_iterator const_iterator;
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typedef typename circular_buffer<T, Alloc>::iterator iterator;
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typedef typename circular_buffer<T, Alloc>::const_reverse_iterator const_reverse_iterator;
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typedef typename circular_buffer<T, Alloc>::reverse_iterator reverse_iterator;
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typedef typename circular_buffer<T, Alloc>::array_range array_range;
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typedef typename circular_buffer<T, Alloc>::const_array_range const_array_range;
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typedef typename circular_buffer<T, Alloc>::param_value_type param_value_type;
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typedef typename circular_buffer<T, Alloc>::return_value_type return_value_type;
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//! Capacity controller of the space optimized circular buffer.
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/*!
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<p><pre>
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class capacity_control {
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size_type m_capacity;
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size_type m_min_capacity;
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public:
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capacity_control(size_type capacity, size_type min_capacity = 0) : m_capacity(capacity), m_min_capacity(min_capacity) {};
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size_type %capacity() const { return m_capacity; }
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size_type min_capacity() const { return m_min_capacity; }
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operator size_type() const { return m_capacity; }
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};</pre></p>
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\pre <code>capacity >= min_capacity</code>
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<p>The <code>capacity()</code> represents the capacity of the <code>circular_buffer_space_optimized</code> and
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the <code>min_capacity()</code> determines the minimal allocated size of its internal buffer.</p>
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<p>The converting constructor of the <code>capacity_control</code> allows implicit conversion from
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<code>size_type</code>-like types which ensures compatibility of creating an instance of the
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<code>circular_buffer_space_optimized</code> with other STL containers. On the other hand the operator
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<code>%size_type()</code> provides implicit conversion to the <code>size_type</code> which allows to treat the
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capacity of the <code>circular_buffer_space_optimized</code> the same way as in the
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<code><a href="circular_buffer.html">circular_buffer</a></code>.</p>
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*/
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typedef cb_details::capacity_control<size_type> capacity_type;
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// Inherited
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using circular_buffer<T, Alloc>::get_allocator;
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using circular_buffer<T, Alloc>::begin;
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using circular_buffer<T, Alloc>::end;
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using circular_buffer<T, Alloc>::rbegin;
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using circular_buffer<T, Alloc>::rend;
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using circular_buffer<T, Alloc>::at;
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using circular_buffer<T, Alloc>::front;
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using circular_buffer<T, Alloc>::back;
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using circular_buffer<T, Alloc>::array_one;
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using circular_buffer<T, Alloc>::array_two;
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using circular_buffer<T, Alloc>::linearize;
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using circular_buffer<T, Alloc>::is_linearized;
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using circular_buffer<T, Alloc>::rotate;
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using circular_buffer<T, Alloc>::size;
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using circular_buffer<T, Alloc>::max_size;
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using circular_buffer<T, Alloc>::empty;
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#if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x564))
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reference operator [] (size_type n) { return circular_buffer<T, Alloc>::operator[](n); }
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return_value_type operator [] (size_type n) const { return circular_buffer<T, Alloc>::operator[](n); }
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#else
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using circular_buffer<T, Alloc>::operator[];
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#endif
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private:
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// Member variables
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//! The capacity controller of the space optimized circular buffer.
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capacity_type m_capacity_ctrl;
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public:
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// Overridden
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//! Is the <code>circular_buffer_space_optimized</code> full?
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/*!
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\return <code>true</code> if the number of elements stored in the <code>circular_buffer_space_optimized</code>
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equals the capacity of the <code>circular_buffer_space_optimized</code>; <code>false</code> otherwise.
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\throws Nothing.
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\par Exception Safety
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No-throw.
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\par Iterator Invalidation
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Does not invalidate any iterators.
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\par Complexity
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Constant (in the size of the <code>circular_buffer_space_optimized</code>).
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\sa <code>empty()</code>
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*/
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bool full() const { return m_capacity_ctrl == size(); }
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/*! \brief Get the maximum number of elements which can be inserted into the
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<code>circular_buffer_space_optimized</code> without overwriting any of already stored elements.
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\return <code>capacity().%capacity() - size()</code>
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\throws Nothing.
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\par Exception Safety
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No-throw.
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\par Iterator Invalidation
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Does not invalidate any iterators.
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\par Complexity
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Constant (in the size of the <code>circular_buffer_space_optimized</code>).
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\sa <code>capacity()</code>, <code>size()</code>, <code>max_size()</code>
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*/
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size_type reserve() const { return m_capacity_ctrl - size(); }
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//! Get the capacity of the <code>circular_buffer_space_optimized</code>.
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/*!
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\return The capacity controller representing the maximum number of elements which can be stored in the
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<code>circular_buffer_space_optimized</code> and the minimal allocated size of the internal buffer.
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\throws Nothing.
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\par Exception Safety
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No-throw.
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\par Iterator Invalidation
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Does not invalidate any iterators.
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\par Complexity
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Constant (in the size of the <code>circular_buffer_space_optimized</code>).
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\sa <code>reserve()</code>, <code>size()</code>, <code>max_size()</code>,
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<code>set_capacity(const capacity_type&)</code>
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*/
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const capacity_type& capacity() const { return m_capacity_ctrl; }
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#if defined(BOOST_CB_TEST)
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// Return the current capacity of the adapted circular buffer.
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/*
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\note This method is not intended to be used directly by the user.
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It is defined only for testing purposes.
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*/
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size_type internal_capacity() const { return circular_buffer<T, Alloc>::capacity(); }
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#endif // #if defined(BOOST_CB_TEST)
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/*! \brief Change the capacity (and the minimal guaranteed amount of allocated memory) of the
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<code>circular_buffer_space_optimized</code>.
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\post <code>capacity() == capacity_ctrl \&\& size() \<= capacity_ctrl.capacity()</code><br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is greater
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than the desired new capacity then number of <code>[size() - capacity_ctrl.capacity()]</code> <b>last</b>
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elements will be removed and the new size will be equal to <code>capacity_ctrl.capacity()</code>.<br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is lower
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than the new capacity then the amount of allocated memory in the internal buffer may be accommodated as
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necessary but it will never drop below <code>capacity_ctrl.min_capacity()</code>.
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\param capacity_ctrl The new capacity controller.
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Exception Safety
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Strong.
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\par Iterator Invalidation
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Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
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equal to <code>end()</code>).
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\par Complexity
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Linear (in <code>min[size(), capacity_ctrl.%capacity()]</code>).
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\note To explicitly clear the extra allocated memory use the <b>shrink-to-fit</b> technique:<br><br>
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<code>%boost::%circular_buffer_space_optimized\<int\> cb(1000);<br>
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...<br>
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%boost::%circular_buffer_space_optimized\<int\>(cb).swap(cb);</code><br><br>
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For more information about the shrink-to-fit technique in STL see
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<a href="http://www.gotw.ca/gotw/054.htm">http://www.gotw.ca/gotw/054.htm</a>.
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\sa <code>rset_capacity(const capacity_type&)</code>,
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<code>\link resize() resize(size_type, const_reference)\endlink</code>
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*/
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void set_capacity(const capacity_type& capacity_ctrl) {
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m_capacity_ctrl = capacity_ctrl;
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if (capacity_ctrl < size()) {
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iterator e = end();
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circular_buffer<T, Alloc>::erase(e - (size() - capacity_ctrl), e);
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}
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adjust_min_capacity();
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}
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//! Change the size of the <code>circular_buffer_space_optimized</code>.
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/*!
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\post <code>size() == new_size \&\& capacity().%capacity() >= new_size</code><br><br>
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If the new size is greater than the current size, copies of <code>item</code> will be inserted at the
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<b>back</b> of the of the <code>circular_buffer_space_optimized</code> in order to achieve the desired
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size. In the case the resulting size exceeds the current capacity the capacity will be set to
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<code>new_size</code>.<br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is greater
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than the desired new size then number of <code>[size() - new_size]</code> <b>last</b> elements will be
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removed. (The capacity will remain unchanged.)<br><br>
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The amount of allocated memory in the internal buffer may be accommodated as necessary.
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\param new_size The new size.
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\param item The element the <code>circular_buffer_space_optimized</code> will be filled with in order to gain
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the requested size. (See the <i>Effect</i>.)
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Exception Safety
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Basic.
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\par Iterator Invalidation
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Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
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equal to <code>end()</code>).
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\par Complexity
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Linear (in the new size of the <code>circular_buffer_space_optimized</code>).
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\sa <code>\link rresize() rresize(size_type, const_reference)\endlink</code>,
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<code>set_capacity(const capacity_type&)</code>
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*/
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void resize(size_type new_size, param_value_type item = value_type()) {
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if (new_size > size()) {
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if (new_size > m_capacity_ctrl)
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m_capacity_ctrl = capacity_type(new_size, m_capacity_ctrl.min_capacity());
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insert(end(), new_size - size(), item);
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} else {
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iterator e = end();
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erase(e - (size() - new_size), e);
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}
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}
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/*! \brief Change the capacity (and the minimal guaranteed amount of allocated memory) of the
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<code>circular_buffer_space_optimized</code>.
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\post <code>capacity() == capacity_ctrl \&\& size() \<= capacity_ctrl</code><br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is greater
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than the desired new capacity then number of <code>[size() - capacity_ctrl.capacity()]</code>
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<b>first</b> elements will be removed and the new size will be equal to
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<code>capacity_ctrl.capacity()</code>.<br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is lower
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than the new capacity then the amount of allocated memory in the internal buffer may be accommodated as
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necessary but it will never drop below <code>capacity_ctrl.min_capacity()</code>.
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\param capacity_ctrl The new capacity controller.
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Exception Safety
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Strong.
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\par Iterator Invalidation
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Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
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equal to <code>end()</code>).
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\par Complexity
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Linear (in <code>min[size(), capacity_ctrl.%capacity()]</code>).
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\sa <code>set_capacity(const capacity_type&)</code>,
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<code>\link rresize() rresize(size_type, const_reference)\endlink</code>
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*/
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void rset_capacity(const capacity_type& capacity_ctrl) {
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m_capacity_ctrl = capacity_ctrl;
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if (capacity_ctrl < size()) {
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iterator b = begin();
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circular_buffer<T, Alloc>::rerase(b, b + (size() - capacity_ctrl));
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}
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adjust_min_capacity();
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}
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//! Change the size of the <code>circular_buffer_space_optimized</code>.
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/*!
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\post <code>size() == new_size \&\& capacity().%capacity() >= new_size</code><br><br>
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If the new size is greater than the current size, copies of <code>item</code> will be inserted at the
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<b>front</b> of the of the <code>circular_buffer_space_optimized</code> in order to achieve the desired
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size. In the case the resulting size exceeds the current capacity the capacity will be set to
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<code>new_size</code>.<br><br>
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If the current number of elements stored in the <code>circular_buffer_space_optimized</code> is greater
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than the desired new size then number of <code>[size() - new_size]</code> <b>first</b> elements will be
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removed. (The capacity will remain unchanged.)<br><br>
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The amount of allocated memory in the internal buffer may be accommodated as necessary.
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\param new_size The new size.
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\param item The element the <code>circular_buffer_space_optimized</code> will be filled with in order to gain
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the requested size. (See the <i>Effect</i>.)
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Exception Safety
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Basic.
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\par Iterator Invalidation
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Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
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equal to <code>end()</code>).
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\par Complexity
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Linear (in the new size of the <code>circular_buffer_space_optimized</code>).
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\sa <code>\link resize() resize(size_type, const_reference)\endlink</code>,
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<code>rset_capacity(const capacity_type&)</code>
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*/
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void rresize(size_type new_size, param_value_type item = value_type()) {
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if (new_size > size()) {
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if (new_size > m_capacity_ctrl)
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m_capacity_ctrl = capacity_type(new_size, m_capacity_ctrl.min_capacity());
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rinsert(begin(), new_size - size(), item);
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} else {
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rerase(begin(), end() - new_size);
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}
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}
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//! Create an empty space optimized circular buffer with zero capacity.
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/*!
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\post <code>capacity().%capacity() == 0 \&\& capacity().min_capacity() == 0 \&\& size() == 0</code>
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\param alloc The allocator.
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\throws Nothing.
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\par Complexity
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Constant.
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\warning Since Boost version 1.36 the behaviour of this constructor has changed. Now it creates a space
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optimized circular buffer with zero capacity.
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*/
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explicit circular_buffer_space_optimized(const allocator_type& alloc = allocator_type())
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: circular_buffer<T, Alloc>(0, alloc)
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, m_capacity_ctrl(0) {}
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//! Create an empty space optimized circular buffer with the specified capacity.
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/*!
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\post <code>capacity() == capacity_ctrl \&\& size() == 0</code><br><br>
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The amount of allocated memory in the internal buffer is <code>capacity_ctrl.min_capacity()</code>.
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\param capacity_ctrl The capacity controller representing the maximum number of elements which can be stored in
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the <code>circular_buffer_space_optimized</code> and the minimal allocated size of the
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internal buffer.
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\param alloc The allocator.
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\par Complexity
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Constant.
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*/
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explicit circular_buffer_space_optimized(capacity_type capacity_ctrl,
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const allocator_type& alloc = allocator_type())
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: circular_buffer<T, Alloc>(capacity_ctrl.min_capacity(), alloc)
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, m_capacity_ctrl(capacity_ctrl) {}
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/*! \brief Create a full space optimized circular buffer with the specified capacity filled with
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<code>capacity_ctrl.%capacity()</code> copies of <code>item</code>.
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\post <code>capacity() == capacity_ctrl \&\& full() \&\& (*this)[0] == item \&\& (*this)[1] == item \&\& ...
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\&\& (*this) [capacity_ctrl.%capacity() - 1] == item </code><br><br>
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The amount of allocated memory in the internal buffer is <code>capacity_ctrl.capacity()</code>.
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\param capacity_ctrl The capacity controller representing the maximum number of elements which can be stored in
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the <code>circular_buffer_space_optimized</code> and the minimal allocated size of the
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internal buffer.
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\param item The element the created <code>circular_buffer_space_optimized</code> will be filled with.
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\param alloc The allocator.
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Complexity
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Linear (in the <code>capacity_ctrl.%capacity()</code>).
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*/
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circular_buffer_space_optimized(capacity_type capacity_ctrl, param_value_type item,
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const allocator_type& alloc = allocator_type())
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: circular_buffer<T, Alloc>(capacity_ctrl.capacity(), item, alloc)
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, m_capacity_ctrl(capacity_ctrl) {}
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/*! \brief Create a space optimized circular buffer with the specified capacity filled with <code>n</code> copies
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of <code>item</code>.
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\pre <code>capacity_ctrl.%capacity() >= n</code>
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\post <code>capacity() == capacity_ctrl \&\& size() == n \&\& (*this)[0] == item \&\& (*this)[1] == item
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\&\& ... \&\& (*this)[n - 1] == item</code><br><br>
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The amount of allocated memory in the internal buffer is
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<code>max[n, capacity_ctrl.min_capacity()]</code>.
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\param capacity_ctrl The capacity controller representing the maximum number of elements which can be stored in
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the <code>circular_buffer_space_optimized</code> and the minimal allocated size of the
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internal buffer.
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\param n The number of elements the created <code>circular_buffer_space_optimized</code> will be filled with.
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\param item The element the created <code>circular_buffer_space_optimized</code> will be filled with.
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\param alloc The allocator.
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\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
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used).
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\throws Whatever <code>T::T(const T&)</code> throws.
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\par Complexity
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Linear (in the <code>n</code>).
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*/
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circular_buffer_space_optimized(capacity_type capacity_ctrl, size_type n, param_value_type item,
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const allocator_type& alloc = allocator_type())
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: circular_buffer<T, Alloc>(init_capacity(capacity_ctrl, n), n, item, alloc)
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, m_capacity_ctrl(capacity_ctrl) {}
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|
|
#if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
|
|
|
|
/*! \cond */
|
|
circular_buffer_space_optimized(const circular_buffer_space_optimized<T, Alloc>& cb)
|
|
: circular_buffer<T, Alloc>(cb.begin(), cb.end())
|
|
, m_capacity_ctrl(cb.m_capacity_ctrl) {}
|
|
|
|
template <class InputIterator>
|
|
circular_buffer_space_optimized(InputIterator first, InputIterator last)
|
|
: circular_buffer<T, Alloc>(first, last)
|
|
, m_capacity_ctrl(circular_buffer<T, Alloc>::capacity()) {}
|
|
|
|
template <class InputIterator>
|
|
circular_buffer_space_optimized(capacity_type capacity_ctrl, InputIterator first, InputIterator last)
|
|
: circular_buffer<T, Alloc>(
|
|
init_capacity(capacity_ctrl, first, last, is_integral<InputIterator>()),
|
|
first, last)
|
|
, m_capacity_ctrl(capacity_ctrl) {
|
|
reduce_capacity(
|
|
is_same< BOOST_DEDUCED_TYPENAME BOOST_ITERATOR_CATEGORY<InputIterator>::type, std::input_iterator_tag >());
|
|
}
|
|
/*! \endcond */
|
|
|
|
#else
|
|
|
|
//! The copy constructor.
|
|
/*!
|
|
Creates a copy of the specified <code>circular_buffer_space_optimized</code>.
|
|
\post <code>*this == cb</code><br><br>
|
|
The amount of allocated memory in the internal buffer is <code>cb.size()</code>.
|
|
\param cb The <code>circular_buffer_space_optimized</code> to be copied.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Complexity
|
|
Linear (in the size of <code>cb</code>).
|
|
*/
|
|
circular_buffer_space_optimized(const circular_buffer_space_optimized<T, Alloc>& cb)
|
|
: circular_buffer<T, Alloc>(cb.begin(), cb.end(), cb.get_allocator())
|
|
, m_capacity_ctrl(cb.m_capacity_ctrl) {}
|
|
|
|
//! Create a full space optimized circular buffer filled with a copy of the range.
|
|
/*!
|
|
\pre Valid range <code>[first, last)</code>.<br>
|
|
<code>first</code> and <code>last</code> have to meet the requirements of
|
|
<a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post <code>capacity().%capacity() == std::distance(first, last) \&\& capacity().min_capacity() == 0 \&\&
|
|
full() \&\& (*this)[0]== *first \&\& (*this)[1] == *(first + 1) \&\& ... \&\&
|
|
(*this)[std::distance(first, last) - 1] == *(last - 1)</code><br><br>
|
|
The amount of allocated memory in the internal buffer is <code>std::distance(first, last)</code>.
|
|
\param first The beginning of the range to be copied.
|
|
\param last The end of the range to be copied.
|
|
\param alloc The allocator.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Complexity
|
|
Linear (in the <code>std::distance(first, last)</code>).
|
|
*/
|
|
template <class InputIterator>
|
|
circular_buffer_space_optimized(InputIterator first, InputIterator last,
|
|
const allocator_type& alloc = allocator_type())
|
|
: circular_buffer<T, Alloc>(first, last, alloc)
|
|
, m_capacity_ctrl(circular_buffer<T, Alloc>::capacity()) {}
|
|
|
|
/*! \brief Create a space optimized circular buffer with the specified capacity (and the minimal guaranteed amount
|
|
of allocated memory) filled with a copy of the range.
|
|
\pre Valid range <code>[first, last)</code>.<br>
|
|
<code>first</code> and <code>last</code> have to meet the requirements of
|
|
<a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post <code>capacity() == capacity_ctrl \&\& size() \<= std::distance(first, last) \&\& (*this)[0]==
|
|
*(last - capacity_ctrl.%capacity()) \&\& (*this)[1] == *(last - capacity_ctrl.%capacity() + 1) \&\& ...
|
|
\&\& (*this)[capacity_ctrl.%capacity() - 1] == *(last - 1)</code><br><br>
|
|
If the number of items to be copied from the range <code>[first, last)</code> is greater than the
|
|
specified <code>capacity_ctrl.%capacity()</code> then only elements from the range
|
|
<code>[last - capacity_ctrl.%capacity(), last)</code> will be copied.<br><br>
|
|
The amount of allocated memory in the internal buffer is <code>max[capacity_ctrl.min_capacity(),
|
|
min[capacity_ctrl.%capacity(), std::distance(first, last)]]</code>.
|
|
\param capacity_ctrl The capacity controller representing the maximum number of elements which can be stored in
|
|
the <code>circular_buffer_space_optimized</code> and the minimal allocated size of the
|
|
internal buffer.
|
|
\param first The beginning of the range to be copied.
|
|
\param last The end of the range to be copied.
|
|
\param alloc The allocator.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Complexity
|
|
Linear (in <code>std::distance(first, last)</code>; in
|
|
<code>min[capacity_ctrl.%capacity(), std::distance(first, last)]</code> if the <code>InputIterator</code>
|
|
is a <a href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">RandomAccessIterator</a>).
|
|
*/
|
|
template <class InputIterator>
|
|
circular_buffer_space_optimized(capacity_type capacity_ctrl, InputIterator first, InputIterator last,
|
|
const allocator_type& alloc = allocator_type())
|
|
: circular_buffer<T, Alloc>(
|
|
init_capacity(capacity_ctrl, first, last, is_integral<InputIterator>()),
|
|
first, last, alloc)
|
|
, m_capacity_ctrl(capacity_ctrl) {
|
|
reduce_capacity(
|
|
is_same< BOOST_DEDUCED_TYPENAME BOOST_ITERATOR_CATEGORY<InputIterator>::type, std::input_iterator_tag >());
|
|
}
|
|
|
|
#endif // #if BOOST_WORKAROUND(BOOST_MSVC, < 1300)
|
|
|
|
#if defined(BOOST_CB_NEVER_DEFINED)
|
|
// This section will never be compiled - the default destructor will be generated instead.
|
|
// Declared only for documentation purpose.
|
|
|
|
//! The destructor.
|
|
/*!
|
|
Destroys the <code>circular_buffer_space_optimized</code>.
|
|
\throws Nothing.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (including
|
|
iterators equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>clear()</code>
|
|
*/
|
|
~circular_buffer_space_optimized();
|
|
|
|
//! no-comment
|
|
void erase_begin(size_type n);
|
|
|
|
//! no-comment
|
|
void erase_end(size_type n);
|
|
|
|
#endif // #if defined(BOOST_CB_NEVER_DEFINED)
|
|
|
|
//! The assign operator.
|
|
/*!
|
|
Makes this <code>circular_buffer_space_optimized</code> to become a copy of the specified
|
|
<code>circular_buffer_space_optimized</code>.
|
|
\post <code>*this == cb</code><br><br>
|
|
The amount of allocated memory in the internal buffer is <code>cb.size()</code>.
|
|
\param cb The <code>circular_buffer_space_optimized</code> to be copied.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Strong.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to this <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of <code>cb</code>).
|
|
\sa <code>\link assign(size_type, param_value_type) assign(size_type, const_reference)\endlink</code>,
|
|
<code>\link assign(capacity_type, size_type, param_value_type)
|
|
assign(capacity_type, size_type, const_reference)\endlink</code>,
|
|
<code>assign(InputIterator, InputIterator)</code>,
|
|
<code>assign(capacity_type, InputIterator, InputIterator)</code>
|
|
*/
|
|
circular_buffer_space_optimized<T, Alloc>& operator = (const circular_buffer_space_optimized<T, Alloc>& cb) {
|
|
if (this == &cb)
|
|
return *this;
|
|
circular_buffer<T, Alloc>::assign(cb.begin(), cb.end());
|
|
m_capacity_ctrl = cb.m_capacity_ctrl;
|
|
return *this;
|
|
}
|
|
|
|
//! Assign <code>n</code> items into the space optimized circular buffer.
|
|
/*!
|
|
The content of the <code>circular_buffer_space_optimized</code> will be removed and replaced with
|
|
<code>n</code> copies of the <code>item</code>.
|
|
\post <code>capacity().%capacity() == n \&\& capacity().min_capacity() == 0 \&\& size() == n \&\& (*this)[0] ==
|
|
item \&\& (*this)[1] == item \&\& ... \&\& (*this) [n - 1] == item</code><br><br>
|
|
The amount of allocated memory in the internal buffer is <code>n</code>.
|
|
\param n The number of elements the <code>circular_buffer_space_optimized</code> will be filled with.
|
|
\param item The element the <code>circular_buffer_space_optimized</code> will be filled with.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the <code>n</code>).
|
|
\sa <code>\link operator=(const circular_buffer_space_optimized&) operator=\endlink</code>,
|
|
<code>\link assign(capacity_type, size_type, param_value_type)
|
|
assign(capacity_type, size_type, const_reference)\endlink</code>,
|
|
<code>assign(InputIterator, InputIterator)</code>,
|
|
<code>assign(capacity_type, InputIterator, InputIterator)</code>
|
|
*/
|
|
void assign(size_type n, param_value_type item) {
|
|
circular_buffer<T, Alloc>::assign(n, item);
|
|
m_capacity_ctrl = capacity_type(n);
|
|
}
|
|
|
|
//! Assign <code>n</code> items into the space optimized circular buffer specifying the capacity.
|
|
/*!
|
|
The capacity of the <code>circular_buffer_space_optimized</code> will be set to the specified value and the
|
|
content of the <code>circular_buffer_space_optimized</code> will be removed and replaced with <code>n</code>
|
|
copies of the <code>item</code>.
|
|
\pre <code>capacity_ctrl.%capacity() >= n</code>
|
|
\post <code>capacity() == capacity_ctrl \&\& size() == n \&\& (*this)[0] == item \&\& (*this)[1] == item
|
|
\&\& ... \&\& (*this) [n - 1] == item </code><br><br>
|
|
The amount of allocated memory will be <code>max[n, capacity_ctrl.min_capacity()]</code>.
|
|
\param capacity_ctrl The new capacity controller.
|
|
\param n The number of elements the <code>circular_buffer_space_optimized</code> will be filled with.
|
|
\param item The element the <code>circular_buffer_space_optimized</code> will be filled with.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the <code>n</code>).
|
|
\sa <code>\link operator=(const circular_buffer_space_optimized&) operator=\endlink</code>,
|
|
<code>\link assign(size_type, param_value_type) assign(size_type, const_reference)\endlink</code>,
|
|
<code>assign(InputIterator, InputIterator)</code>,
|
|
<code>assign(capacity_type, InputIterator, InputIterator)</code>
|
|
*/
|
|
void assign(capacity_type capacity_ctrl, size_type n, param_value_type item) {
|
|
BOOST_CB_ASSERT(capacity_ctrl.capacity() >= n); // check for new capacity lower than n
|
|
circular_buffer<T, Alloc>::assign((std::max)(capacity_ctrl.min_capacity(), n), n, item);
|
|
m_capacity_ctrl = capacity_ctrl;
|
|
}
|
|
|
|
//! Assign a copy of the range into the space optimized circular buffer.
|
|
/*!
|
|
The content of the <code>circular_buffer_space_optimized</code> will be removed and replaced with copies of
|
|
elements from the specified range.
|
|
\pre Valid range <code>[first, last)</code>.<br>
|
|
<code>first</code> and <code>last</code> have to meet the requirements of
|
|
<a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post <code>capacity().%capacity() == std::distance(first, last) \&\& capacity().min_capacity() == 0 \&\&
|
|
size() == std::distance(first, last) \&\& (*this)[0]== *first \&\& (*this)[1] == *(first + 1) \&\& ...
|
|
\&\& (*this)[std::distance(first, last) - 1] == *(last - 1)</code><br><br>
|
|
The amount of allocated memory in the internal buffer is <code>std::distance(first, last)</code>.
|
|
\param first The beginning of the range to be copied.
|
|
\param last The end of the range to be copied.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the <code>std::distance(first, last)</code>).
|
|
\sa <code>\link operator=(const circular_buffer_space_optimized&) operator=\endlink</code>,
|
|
<code>\link assign(size_type, param_value_type) assign(size_type, const_reference)\endlink</code>,
|
|
<code>\link assign(capacity_type, size_type, param_value_type)
|
|
assign(capacity_type, size_type, const_reference)\endlink</code>,
|
|
<code>assign(capacity_type, InputIterator, InputIterator)</code>
|
|
*/
|
|
template <class InputIterator>
|
|
void assign(InputIterator first, InputIterator last) {
|
|
circular_buffer<T, Alloc>::assign(first, last);
|
|
m_capacity_ctrl = capacity_type(circular_buffer<T, Alloc>::capacity());
|
|
}
|
|
|
|
//! Assign a copy of the range into the space optimized circular buffer specifying the capacity.
|
|
/*!
|
|
The capacity of the <code>circular_buffer_space_optimized</code> will be set to the specified value and the
|
|
content of the <code>circular_buffer_space_optimized</code> will be removed and replaced with copies of
|
|
elements from the specified range.
|
|
\pre Valid range <code>[first, last)</code>.<br>
|
|
<code>first</code> and <code>last</code> have to meet the requirements of
|
|
<a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post <code>capacity() == capacity_ctrl \&\& size() \<= std::distance(first, last) \&\&
|
|
(*this)[0]== *(last - capacity) \&\& (*this)[1] == *(last - capacity + 1) \&\& ... \&\&
|
|
(*this)[capacity - 1] == *(last - 1)</code><br><br>
|
|
If the number of items to be copied from the range <code>[first, last)</code> is greater than the
|
|
specified <code>capacity</code> then only elements from the range <code>[last - capacity, last)</code>
|
|
will be copied.<br><br> The amount of allocated memory in the internal buffer is
|
|
<code>max[std::distance(first, last), capacity_ctrl.min_capacity()]</code>.
|
|
\param capacity_ctrl The new capacity controller.
|
|
\param first The beginning of the range to be copied.
|
|
\param last The end of the range to be copied.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in <code>std::distance(first, last)</code>; in
|
|
<code>min[capacity_ctrl.%capacity(), std::distance(first, last)]</code> if the <code>InputIterator</code>
|
|
is a <a href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">RandomAccessIterator</a>).
|
|
\sa <code>\link operator=(const circular_buffer_space_optimized&) operator=\endlink</code>,
|
|
<code>\link assign(size_type, param_value_type) assign(size_type, const_reference)\endlink</code>,
|
|
<code>\link assign(capacity_type, size_type, param_value_type)
|
|
assign(capacity_type, size_type, const_reference)\endlink</code>,
|
|
<code>assign(InputIterator, InputIterator)</code>
|
|
*/
|
|
template <class InputIterator>
|
|
void assign(capacity_type capacity_ctrl, InputIterator first, InputIterator last) {
|
|
m_capacity_ctrl = capacity_ctrl;
|
|
circular_buffer<T, Alloc>::assign(capacity_ctrl, first, last);
|
|
}
|
|
|
|
//! Swap the contents of two space optimized circular buffers.
|
|
/*!
|
|
\post <code>this</code> contains elements of <code>cb</code> and vice versa; the capacity and the amount of
|
|
allocated memory in the internal buffer of <code>this</code> equal to the capacity and the amount of
|
|
allocated memory of <code>cb</code> and vice versa.
|
|
\param cb The <code>circular_buffer_space_optimized</code> whose content will be swapped.
|
|
\throws Nothing.
|
|
\par Exception Safety
|
|
No-throw.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators of both <code>circular_buffer_space_optimized</code> containers. (On the other
|
|
hand the iterators still point to the same elements but within another container. If you want to rely on
|
|
this feature you have to turn the <a href="circular_buffer.html#debug">Debug Support</a> off otherwise an
|
|
assertion will report an error if such invalidated iterator is used.)
|
|
\par Complexity
|
|
Constant (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>\link swap(circular_buffer<T, Alloc>&, circular_buffer<T, Alloc>&)
|
|
swap(circular_buffer_space_optimized<T, Alloc>&, circular_buffer_space_optimized<T, Alloc>&)\endlink</code>
|
|
*/
|
|
void swap(circular_buffer_space_optimized<T, Alloc>& cb) {
|
|
std::swap(m_capacity_ctrl, cb.m_capacity_ctrl);
|
|
circular_buffer<T, Alloc>::swap(cb);
|
|
}
|
|
|
|
//! Insert a new element at the end of the space optimized circular buffer.
|
|
/*!
|
|
\post if <code>capacity().%capacity() > 0</code> then <code>back() == item</code><br>
|
|
If the <code>circular_buffer_space_optimized</code> is full, the first element will be removed. If the
|
|
capacity is <code>0</code>, nothing will be inserted.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param item The element to be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>\link push_front() push_front(const_reference)\endlink</code>, <code>pop_back()</code>,
|
|
<code>pop_front()</code>
|
|
*/
|
|
void push_back(param_value_type item = value_type()) {
|
|
check_low_capacity();
|
|
circular_buffer<T, Alloc>::push_back(item);
|
|
}
|
|
|
|
//! Insert a new element at the beginning of the space optimized circular buffer.
|
|
/*!
|
|
\post if <code>capacity().%capacity() > 0</code> then <code>front() == item</code><br>
|
|
If the <code>circular_buffer_space_optimized</code> is full, the last element will be removed. If the
|
|
capacity is <code>0</code>, nothing will be inserted.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param item The element to be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>\link push_back() push_back(const_reference)\endlink</code>, <code>pop_back()</code>,
|
|
<code>pop_front()</code>
|
|
*/
|
|
void push_front(param_value_type item = value_type()) {
|
|
check_low_capacity();
|
|
circular_buffer<T, Alloc>::push_front(item);
|
|
}
|
|
|
|
//! Remove the last element from the space optimized circular buffer.
|
|
/*!
|
|
\pre <code>!empty()</code>
|
|
\post The last element is removed from the <code>circular_buffer_space_optimized</code>.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>pop_front()</code>, <code>\link push_back() push_back(const_reference)\endlink</code>,
|
|
<code>\link push_front() push_front(const_reference)\endlink</code>
|
|
*/
|
|
void pop_back() {
|
|
circular_buffer<T, Alloc>::pop_back();
|
|
check_high_capacity();
|
|
}
|
|
|
|
//! Remove the first element from the space optimized circular buffer.
|
|
/*!
|
|
\pre <code>!empty()</code>
|
|
\post The first element is removed from the <code>circular_buffer_space_optimized</code>.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>pop_back()</code>, <code>\link push_back() push_back(const_reference)\endlink</code>,
|
|
<code>\link push_front() push_front(const_reference)\endlink</code>
|
|
*/
|
|
void pop_front() {
|
|
circular_buffer<T, Alloc>::pop_front();
|
|
check_high_capacity();
|
|
}
|
|
|
|
//! Insert an element at the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.
|
|
\post The <code>item</code> will be inserted at the position <code>pos</code>.<br>
|
|
If the <code>circular_buffer_space_optimized</code> is full, the first element will be overwritten. If
|
|
the <code>circular_buffer_space_optimized</code> is full and the <code>pos</code> points to
|
|
<code>begin()</code>, then the <code>item</code> will not be inserted. If the capacity is <code>0</code>,
|
|
nothing will be inserted.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position where the <code>item</code> will be inserted.
|
|
\param item The element to be inserted.
|
|
\return Iterator to the inserted element or <code>begin()</code> if the <code>item</code> is not inserted. (See
|
|
the <i>Effect</i>.)
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>\link insert(iterator, size_type, param_value_type)
|
|
insert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>insert(iterator, InputIterator, InputIterator)</code>,
|
|
<code>\link rinsert(iterator, param_value_type) rinsert(iterator, value_type)\endlink</code>,
|
|
<code>\link rinsert(iterator, size_type, param_value_type)
|
|
rinsert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>rinsert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
iterator insert(iterator pos, param_value_type item = value_type()) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity();
|
|
return circular_buffer<T, Alloc>::insert(begin() + index, item);
|
|
}
|
|
|
|
//! Insert <code>n</code> copies of the <code>item</code> at the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.
|
|
\post The number of <code>min[n, (pos - begin()) + reserve()]</code> elements will be inserted at the position
|
|
<code>pos</code>.<br>The number of <code>min[pos - begin(), max[0, n - reserve()]]</code> elements will
|
|
be overwritten at the beginning of the <code>circular_buffer_space_optimized</code>.<br>(See
|
|
<i>Example</i> for the explanation.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position where the <code>item</code>s will be inserted.
|
|
\param n The number of <code>item</code>s the to be inserted.
|
|
\param item The element whose copies will be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in <code>min[capacity().%capacity(), size() + n]</code>).
|
|
\par Example
|
|
Consider a <code>circular_buffer_space_optimized</code> with the capacity of 6 and the size of 4. Its
|
|
internal buffer may look like the one below.<br><br>
|
|
<code>|1|2|3|4| | |</code><br>
|
|
<code>p ---^</code><br><br>After inserting 5 elements at the position <code>p</code>:<br><br>
|
|
<code>insert(p, (size_t)5, 0);</code><br><br>actually only 4 elements get inserted and elements
|
|
<code>1</code> and <code>2</code> are overwritten. This is due to the fact the insert operation preserves
|
|
the capacity. After insertion the internal buffer looks like this:<br><br><code>|0|0|0|0|3|4|</code><br>
|
|
<br>For comparison if the capacity would not be preserved the internal buffer would then result in
|
|
<code>|1|2|0|0|0|0|0|3|4|</code>.
|
|
\sa <code>\link insert(iterator, param_value_type) insert(iterator, value_type)\endlink</code>,
|
|
<code>insert(iterator, InputIterator, InputIterator)</code>,
|
|
<code>\link rinsert(iterator, param_value_type) rinsert(iterator, value_type)\endlink</code>,
|
|
<code>\link rinsert(iterator, size_type, param_value_type)
|
|
rinsert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>rinsert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
void insert(iterator pos, size_type n, param_value_type item) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity(n);
|
|
circular_buffer<T, Alloc>::insert(begin() + index, n, item);
|
|
}
|
|
|
|
//! Insert the range <code>[first, last)</code> at the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.<br>Valid range <code>[first, last)</code> where <code>first</code> and <code>last</code> meet the
|
|
requirements of an <a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post Elements from the range
|
|
<code>[first + max[0, distance(first, last) - (pos - begin()) - reserve()], last)</code> will be
|
|
inserted at the position <code>pos</code>.<br>The number of <code>min[pos - begin(), max[0,
|
|
distance(first, last) - reserve()]]</code> elements will be overwritten at the beginning of the
|
|
<code>circular_buffer_space_optimized</code>.<br>(See <i>Example</i> for the explanation.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position where the range will be inserted.
|
|
\param first The beginning of the range to be inserted.
|
|
\param last The end of the range to be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in <code>[size() + std::distance(first, last)]</code>; in
|
|
<code>min[capacity().%capacity(), size() + std::distance(first, last)]</code> if the
|
|
<code>InputIterator</code> is a
|
|
<a href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">RandomAccessIterator</a>).
|
|
\par Example
|
|
Consider a <code>circular_buffer_space_optimized</code> with the capacity of 6 and the size of 4. Its
|
|
internal buffer may look like the one below.<br><br>
|
|
<code>|1|2|3|4| | |</code><br>
|
|
<code>p ---^</code><br><br>After inserting a range of elements at the position <code>p</code>:<br><br>
|
|
<code>int array[] = { 5, 6, 7, 8, 9 };</code><br><code>insert(p, array, array + 5);</code><br><br>
|
|
actually only elements <code>6</code>, <code>7</code>, <code>8</code> and <code>9</code> from the
|
|
specified range get inserted and elements <code>1</code> and <code>2</code> are overwritten. This is due
|
|
to the fact the insert operation preserves the capacity. After insertion the internal buffer looks like
|
|
this:<br><br><code>|6|7|8|9|3|4|</code><br><br>For comparison if the capacity would not be preserved the
|
|
internal buffer would then result in <code>|1|2|5|6|7|8|9|3|4|</code>.
|
|
\sa <code>\link insert(iterator, param_value_type) insert(iterator, value_type)\endlink</code>,
|
|
<code>\link insert(iterator, size_type, param_value_type)
|
|
insert(iterator, size_type, value_type)\endlink</code>, <code>\link rinsert(iterator, param_value_type)
|
|
rinsert(iterator, value_type)\endlink</code>, <code>\link rinsert(iterator, size_type, param_value_type)
|
|
rinsert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>rinsert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
template <class InputIterator>
|
|
void insert(iterator pos, InputIterator first, InputIterator last) {
|
|
insert(pos, first, last, is_integral<InputIterator>());
|
|
}
|
|
|
|
//! Insert an element before the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.
|
|
\post The <code>item</code> will be inserted before the position <code>pos</code>.<br>
|
|
If the <code>circular_buffer_space_optimized</code> is full, the last element will be overwritten. If the
|
|
<code>circular_buffer_space_optimized</code> is full and the <code>pos</code> points to
|
|
<code>end()</code>, then the <code>item</code> will not be inserted. If the capacity is <code>0</code>,
|
|
nothing will be inserted.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position before which the <code>item</code> will be inserted.
|
|
\param item The element to be inserted.
|
|
\return Iterator to the inserted element or <code>end()</code> if the <code>item</code> is not inserted. (See
|
|
the <i>Effect</i>.)
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>\link rinsert(iterator, size_type, param_value_type)
|
|
rinsert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>rinsert(iterator, InputIterator, InputIterator)</code>,
|
|
<code>\link insert(iterator, param_value_type) insert(iterator, value_type)\endlink</code>,
|
|
<code>\link insert(iterator, size_type, param_value_type)
|
|
insert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>insert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
iterator rinsert(iterator pos, param_value_type item = value_type()) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity();
|
|
return circular_buffer<T, Alloc>::rinsert(begin() + index, item);
|
|
}
|
|
|
|
//! Insert <code>n</code> copies of the <code>item</code> before the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.
|
|
\post The number of <code>min[n, (end() - pos) + reserve()]</code> elements will be inserted before the
|
|
position <code>pos</code>.<br>The number of <code>min[end() - pos, max[0, n - reserve()]]</code> elements
|
|
will be overwritten at the end of the <code>circular_buffer_space_optimized</code>.<br>(See
|
|
<i>Example</i> for the explanation.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position where the <code>item</code>s will be inserted.
|
|
\param n The number of <code>item</code>s the to be inserted.
|
|
\param item The element whose copies will be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in <code>min[capacity().%capacity(), size() + n]</code>).
|
|
\par Example
|
|
Consider a <code>circular_buffer_space_optimized</code> with the capacity of 6 and the size of 4. Its
|
|
internal buffer may look like the one below.<br><br>
|
|
<code>|1|2|3|4| | |</code><br>
|
|
<code>p ---^</code><br><br>After inserting 5 elements before the position <code>p</code>:<br><br>
|
|
<code>rinsert(p, (size_t)5, 0);</code><br><br>actually only 4 elements get inserted and elements
|
|
<code>3</code> and <code>4</code> are overwritten. This is due to the fact the rinsert operation preserves
|
|
the capacity. After insertion the internal buffer looks like this:<br><br><code>|1|2|0|0|0|0|</code><br>
|
|
<br>For comparison if the capacity would not be preserved the internal buffer would then result in
|
|
<code>|1|2|0|0|0|0|0|3|4|</code>.
|
|
\sa <code>\link rinsert(iterator, param_value_type) rinsert(iterator, value_type)\endlink</code>,
|
|
<code>rinsert(iterator, InputIterator, InputIterator)</code>,
|
|
<code>\link insert(iterator, param_value_type) insert(iterator, value_type)\endlink</code>,
|
|
<code>\link insert(iterator, size_type, param_value_type)
|
|
insert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>insert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
void rinsert(iterator pos, size_type n, param_value_type item) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity(n);
|
|
circular_buffer<T, Alloc>::rinsert(begin() + index, n, item);
|
|
}
|
|
|
|
//! Insert the range <code>[first, last)</code> before the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> or its
|
|
end.<br>
|
|
Valid range <code>[first, last)</code> where <code>first</code> and <code>last</code> meet the
|
|
requirements of an <a href="http://www.sgi.com/tech/stl/InputIterator.html">InputIterator</a>.
|
|
\post Elements from the range
|
|
<code>[first, last - max[0, distance(first, last) - (end() - pos) - reserve()])</code> will be inserted
|
|
before the position <code>pos</code>.<br>The number of <code>min[end() - pos, max[0,
|
|
distance(first, last) - reserve()]]</code> elements will be overwritten at the end of the
|
|
<code>circular_buffer</code>.<br>(See <i>Example</i> for the explanation.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively increased.
|
|
\param pos An iterator specifying the position where the range will be inserted.
|
|
\param first The beginning of the range to be inserted.
|
|
\param last The end of the range to be inserted.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::T(const T&)</code> throws.
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in <code>[size() + std::distance(first, last)]</code>; in
|
|
<code>min[capacity().%capacity(), size() + std::distance(first, last)]</code> if the
|
|
<code>InputIterator</code> is a
|
|
<a href="http://www.sgi.com/tech/stl/RandomAccessIterator.html">RandomAccessIterator</a>).
|
|
\par Example
|
|
Consider a <code>circular_buffer_space_optimized</code> with the capacity of 6 and the size of 4. Its
|
|
internal buffer may look like the one below.<br><br>
|
|
<code>|1|2|3|4| | |</code><br>
|
|
<code>p ---^</code><br><br>After inserting a range of elements before the position <code>p</code>:<br><br>
|
|
<code>int array[] = { 5, 6, 7, 8, 9 };</code><br><code>insert(p, array, array + 5);</code><br><br>
|
|
actually only elements <code>5</code>, <code>6</code>, <code>7</code> and <code>8</code> from the
|
|
specified range get inserted and elements <code>3</code> and <code>4</code> are overwritten. This is due
|
|
to the fact the rinsert operation preserves the capacity. After insertion the internal buffer looks like
|
|
this:<br><br><code>|1|2|5|6|7|8|</code><br><br>For comparison if the capacity would not be preserved the
|
|
internal buffer would then result in <code>|1|2|5|6|7|8|9|3|4|</code>.
|
|
\sa <code>\link rinsert(iterator, param_value_type) rinsert(iterator, value_type)\endlink</code>,
|
|
<code>\link rinsert(iterator, size_type, param_value_type)
|
|
rinsert(iterator, size_type, value_type)\endlink</code>, <code>\link insert(iterator, param_value_type)
|
|
insert(iterator, value_type)\endlink</code>, <code>\link insert(iterator, size_type, param_value_type)
|
|
insert(iterator, size_type, value_type)\endlink</code>,
|
|
<code>insert(iterator, InputIterator, InputIterator)</code>
|
|
*/
|
|
template <class InputIterator>
|
|
void rinsert(iterator pos, InputIterator first, InputIterator last) {
|
|
rinsert(pos, first, last, is_integral<InputIterator>());
|
|
}
|
|
|
|
//! Remove an element at the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> (but not
|
|
an <code>end()</code>).
|
|
\post The element at the position <code>pos</code> is removed.<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\param pos An iterator pointing at the element to be removed.
|
|
\return Iterator to the first element remaining beyond the removed element or <code>end()</code> if no such
|
|
element exists.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>erase(iterator, iterator)</code>, <code>rerase(iterator)</code>,
|
|
<code>rerase(iterator, iterator)</code>, <code>clear()</code>
|
|
*/
|
|
iterator erase(iterator pos) {
|
|
iterator it = circular_buffer<T, Alloc>::erase(pos);
|
|
size_type index = it - begin();
|
|
check_high_capacity();
|
|
return begin() + index;
|
|
}
|
|
|
|
//! Erase the range <code>[first, last)</code>.
|
|
/*!
|
|
\pre Valid range <code>[first, last)</code>.
|
|
\post The elements from the range <code>[first, last)</code> are removed. (If <code>first == last</code>
|
|
nothing is removed.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\param first The beginning of the range to be removed.
|
|
\param last The end of the range to be removed.
|
|
\return Iterator to the first element remaining beyond the removed elements or <code>end()</code> if no such
|
|
element exists.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>erase(iterator)</code>, <code>rerase(iterator)</code>, <code>rerase(iterator, iterator)</code>,
|
|
<code>clear()</code>
|
|
*/
|
|
iterator erase(iterator first, iterator last) {
|
|
iterator it = circular_buffer<T, Alloc>::erase(first, last);
|
|
size_type index = it - begin();
|
|
check_high_capacity();
|
|
return begin() + index;
|
|
}
|
|
|
|
//! Remove an element at the specified position.
|
|
/*!
|
|
\pre <code>pos</code> is a valid iterator pointing to the <code>circular_buffer_space_optimized</code> (but not
|
|
an <code>end()</code>).<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\post The element at the position <code>pos</code> is removed.
|
|
\param pos An iterator pointing at the element to be removed.
|
|
\return Iterator to the first element remaining in front of the removed element or <code>begin()</code> if no
|
|
such element exists.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\note Basically there is no difference between <code>erase(iterator)</code> and this method. It is implemented
|
|
only for consistency with the base <code><a href="circular_buffer.html">circular_buffer</a></code>.
|
|
\sa <code>erase(iterator)</code>, <code>erase(iterator, iterator)</code>,
|
|
<code>rerase(iterator, iterator)</code>, <code>clear()</code>
|
|
*/
|
|
iterator rerase(iterator pos) {
|
|
iterator it = circular_buffer<T, Alloc>::rerase(pos);
|
|
size_type index = it - begin();
|
|
check_high_capacity();
|
|
return begin() + index;
|
|
}
|
|
|
|
//! Erase the range <code>[first, last)</code>.
|
|
/*!
|
|
\pre Valid range <code>[first, last)</code>.
|
|
\post The elements from the range <code>[first, last)</code> are removed. (If <code>first == last</code>
|
|
nothing is removed.)<br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\param first The beginning of the range to be removed.
|
|
\param last The end of the range to be removed.
|
|
\return Iterator to the first element remaining in front of the removed elements or <code>begin()</code> if no
|
|
such element exists.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\throws Whatever <code>T::operator = (const T&)</code> throws.
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\note Basically there is no difference between <code>erase(iterator, iterator)</code> and this method. It is
|
|
implemented only for consistency with the base
|
|
<code><a href="circular_buffer.html">circular_buffer</a></code>.
|
|
\sa <code>erase(iterator)</code>, <code>erase(iterator, iterator)</code>, <code>rerase(iterator)</code>,
|
|
<code>clear()</code>
|
|
*/
|
|
iterator rerase(iterator first, iterator last) {
|
|
iterator it = circular_buffer<T, Alloc>::rerase(first, last);
|
|
size_type index = it - begin();
|
|
check_high_capacity();
|
|
return begin() + index;
|
|
}
|
|
|
|
//! Remove all stored elements from the space optimized circular buffer.
|
|
/*!
|
|
\post <code>size() == 0</code><br><br>
|
|
The amount of allocated memory in the internal buffer may be predictively decreased.
|
|
\throws "An allocation error" if memory is exhausted (<code>std::bad_alloc</code> if the standard allocator is
|
|
used).
|
|
\par Exception Safety
|
|
Basic.
|
|
\par Iterator Invalidation
|
|
Invalidates all iterators pointing to the <code>circular_buffer_space_optimized</code> (except iterators
|
|
equal to <code>end()</code>).
|
|
\par Complexity
|
|
Linear (in the size of the <code>circular_buffer_space_optimized</code>).
|
|
\sa <code>~circular_buffer_space_optimized()</code>, <code>erase(iterator)</code>,
|
|
<code>erase(iterator, iterator)</code>, <code>rerase(iterator)</code>,
|
|
<code>rerase(iterator, iterator)</code>
|
|
*/
|
|
void clear() { erase(begin(), end()); }
|
|
|
|
private:
|
|
// Helper methods
|
|
|
|
//! Adjust the amount of allocated memory.
|
|
void adjust_min_capacity() {
|
|
if (m_capacity_ctrl.min_capacity() > circular_buffer<T, Alloc>::capacity())
|
|
circular_buffer<T, Alloc>::set_capacity(m_capacity_ctrl.min_capacity());
|
|
else
|
|
check_high_capacity();
|
|
}
|
|
|
|
//! Ensure the reserve for possible growth up.
|
|
size_type ensure_reserve(size_type new_capacity, size_type buffer_size) const {
|
|
if (buffer_size + new_capacity / 5 >= new_capacity)
|
|
new_capacity *= 2; // ensure at least 20% reserve
|
|
if (new_capacity > m_capacity_ctrl)
|
|
return m_capacity_ctrl;
|
|
return new_capacity;
|
|
}
|
|
|
|
//! Check for low capacity.
|
|
/*
|
|
\post If the capacity is low it will be increased.
|
|
*/
|
|
void check_low_capacity(size_type n = 1) {
|
|
size_type new_size = size() + n;
|
|
size_type new_capacity = circular_buffer<T, Alloc>::capacity();
|
|
if (new_size > new_capacity) {
|
|
if (new_capacity == 0)
|
|
new_capacity = 1;
|
|
for (; new_size > new_capacity; new_capacity *= 2) {}
|
|
circular_buffer<T, Alloc>::set_capacity(
|
|
ensure_reserve(new_capacity, new_size));
|
|
}
|
|
#if BOOST_CB_ENABLE_DEBUG
|
|
this->invalidate_iterators_except(end());
|
|
#endif
|
|
}
|
|
|
|
//! Check for high capacity.
|
|
/*
|
|
\post If the capacity is high it will be decreased.
|
|
*/
|
|
void check_high_capacity() {
|
|
size_type new_capacity = circular_buffer<T, Alloc>::capacity();
|
|
while (new_capacity / 3 >= size()) { // (new_capacity / 3) -> avoid oscillations
|
|
new_capacity /= 2;
|
|
if (new_capacity <= m_capacity_ctrl.min_capacity()) {
|
|
new_capacity = m_capacity_ctrl.min_capacity();
|
|
break;
|
|
}
|
|
}
|
|
circular_buffer<T, Alloc>::set_capacity(
|
|
ensure_reserve(new_capacity, size()));
|
|
#if BOOST_CB_ENABLE_DEBUG
|
|
this->invalidate_iterators_except(end());
|
|
#endif
|
|
}
|
|
|
|
//! Specialized method for reducing the capacity.
|
|
void reduce_capacity(const true_type&) {
|
|
circular_buffer<T, Alloc>::set_capacity((std::max)(m_capacity_ctrl.min_capacity(), size()));
|
|
}
|
|
|
|
//! Specialized method for reducing the capacity.
|
|
void reduce_capacity(const false_type&) {}
|
|
|
|
//! Determine the initial capacity.
|
|
static size_type init_capacity(const capacity_type& capacity_ctrl, size_type n) {
|
|
BOOST_CB_ASSERT(capacity_ctrl.capacity() >= n); // check for capacity lower than n
|
|
return (std::max)(capacity_ctrl.min_capacity(), n);
|
|
}
|
|
|
|
//! Specialized method for determining the initial capacity.
|
|
template <class IntegralType>
|
|
static size_type init_capacity(const capacity_type& capacity_ctrl, IntegralType n, IntegralType item,
|
|
const true_type&) {
|
|
return init_capacity(capacity_ctrl, static_cast<size_type>(n));
|
|
}
|
|
|
|
//! Specialized method for determining the initial capacity.
|
|
template <class Iterator>
|
|
static size_type init_capacity(const capacity_type& capacity_ctrl, Iterator first, Iterator last,
|
|
const false_type&) {
|
|
BOOST_CB_IS_CONVERTIBLE(Iterator, value_type); // check for invalid iterator type
|
|
#if BOOST_WORKAROUND(__BORLANDC__, BOOST_TESTED_AT(0x581))
|
|
return init_capacity(capacity_ctrl, first, last, BOOST_ITERATOR_CATEGORY<Iterator>::type());
|
|
#else
|
|
return init_capacity(
|
|
capacity_ctrl, first, last, BOOST_DEDUCED_TYPENAME BOOST_ITERATOR_CATEGORY<Iterator>::type());
|
|
#endif
|
|
}
|
|
|
|
//! Specialized method for determining the initial capacity.
|
|
template <class InputIterator>
|
|
static size_type init_capacity(const capacity_type& capacity_ctrl, InputIterator first, InputIterator last,
|
|
const std::input_iterator_tag&) {
|
|
return capacity_ctrl.capacity();
|
|
}
|
|
|
|
//! Specialized method for determining the initial capacity.
|
|
template <class ForwardIterator>
|
|
static size_type init_capacity(const capacity_type& capacity_ctrl, ForwardIterator first, ForwardIterator last,
|
|
const std::forward_iterator_tag&) {
|
|
BOOST_CB_ASSERT(std::distance(first, last) >= 0); // check for wrong range
|
|
return (std::max)(capacity_ctrl.min_capacity(),
|
|
(std::min)(capacity_ctrl.capacity(), static_cast<size_type>(std::distance(first, last))));
|
|
}
|
|
|
|
//! Specialized insert method.
|
|
template <class IntegralType>
|
|
void insert(const iterator& pos, IntegralType n, IntegralType item, const true_type&) {
|
|
insert(pos, static_cast<size_type>(n), static_cast<value_type>(item));
|
|
}
|
|
|
|
//! Specialized insert method.
|
|
template <class Iterator>
|
|
void insert(const iterator& pos, Iterator first, Iterator last, const false_type&) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity(std::distance(first, last));
|
|
circular_buffer<T, Alloc>::insert(begin() + index, first, last);
|
|
}
|
|
|
|
//! Specialized rinsert method.
|
|
template <class IntegralType>
|
|
void rinsert(const iterator& pos, IntegralType n, IntegralType item, const true_type&) {
|
|
rinsert(pos, static_cast<size_type>(n), static_cast<value_type>(item));
|
|
}
|
|
|
|
//! Specialized rinsert method.
|
|
template <class Iterator>
|
|
void rinsert(const iterator& pos, Iterator first, Iterator last, const false_type&) {
|
|
size_type index = pos - begin();
|
|
check_low_capacity(std::distance(first, last));
|
|
circular_buffer<T, Alloc>::rinsert(begin() + index, first, last);
|
|
}
|
|
};
|
|
|
|
// Non-member functions
|
|
|
|
//! Test two space optimized circular buffers for equality.
|
|
template <class T, class Alloc>
|
|
inline bool operator == (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return lhs.size() == rhs.size() &&
|
|
std::equal(lhs.begin(), lhs.end(), rhs.begin());
|
|
}
|
|
|
|
//! Lexicographical comparison.
|
|
template <class T, class Alloc>
|
|
inline bool operator < (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return std::lexicographical_compare(
|
|
lhs.begin(), lhs.end(), rhs.begin(), rhs.end());
|
|
}
|
|
|
|
#if !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) || BOOST_WORKAROUND(BOOST_MSVC, BOOST_TESTED_AT(1310))
|
|
|
|
//! Test two space optimized circular buffers for non-equality.
|
|
template <class T, class Alloc>
|
|
inline bool operator != (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return !(lhs == rhs);
|
|
}
|
|
|
|
//! Lexicographical comparison.
|
|
template <class T, class Alloc>
|
|
inline bool operator > (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return rhs < lhs;
|
|
}
|
|
|
|
//! Lexicographical comparison.
|
|
template <class T, class Alloc>
|
|
inline bool operator <= (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return !(rhs < lhs);
|
|
}
|
|
|
|
//! Lexicographical comparison.
|
|
template <class T, class Alloc>
|
|
inline bool operator >= (const circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
const circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
return !(lhs < rhs);
|
|
}
|
|
|
|
//! Swap the contents of two space optimized circular buffers.
|
|
template <class T, class Alloc>
|
|
inline void swap(circular_buffer_space_optimized<T, Alloc>& lhs,
|
|
circular_buffer_space_optimized<T, Alloc>& rhs) {
|
|
lhs.swap(rhs);
|
|
}
|
|
|
|
#endif // #if !defined(BOOST_NO_FUNCTION_TEMPLATE_ORDERING) || BOOST_WORKAROUND(BOOST_MSVC, BOOST_TESTED_AT(1310))
|
|
|
|
} // namespace boost
|
|
|
|
#endif // #if !defined(BOOST_CIRCULAR_BUFFER_SPACE_OPTIMIZED_HPP)
|