// Safe iterator implementation -*- C++ -*-
// Copyright (C) 2003, 2004, 2005, 2006, 2009, 2010, 2011, 2012
// Free Software Foundation, Inc.
//
// This file is part of the GNU ISO C++ Library. This library is free
// software; you can redistribute it and/or modify it under the
// terms of the GNU General Public License as published by the
// Free Software Foundation; either version 3, or (at your option)
// any later version.
// This library is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
// GNU General Public License for more details.
// Under Section 7 of GPL version 3, you are granted additional
// permissions described in the GCC Runtime Library Exception, version
// 3.1, as published by the Free Software Foundation.
// You should have received a copy of the GNU General Public License and
// a copy of the GCC Runtime Library Exception along with this program;
// see the files COPYING3 and COPYING.RUNTIME respectively. If not, see
// .
/** @file debug/safe_iterator.h
* This file is a GNU debug extension to the Standard C++ Library.
*/
#ifndef _GLIBCXX_DEBUG_SAFE_ITERATOR_H
#define _GLIBCXX_DEBUG_SAFE_ITERATOR_H 1
#include
#include
#include
#include
#include
#include // for _Iter_base
#include
namespace __gnu_debug
{
/** Helper struct to deal with sequence offering a before_begin
* iterator.
**/
template
struct _BeforeBeginHelper
{
typedef typename _Sequence::const_iterator _It;
typedef typename _It::iterator_type _BaseIt;
static bool
_M_Is(_BaseIt __it, const _Sequence* __seq)
{ return false; }
};
/** Iterators that derive from _Safe_iterator_base but that aren't
* _Safe_iterators can be determined singular or non-singular via
* _Safe_iterator_base.
*/
inline bool
__check_singular_aux(const _Safe_iterator_base* __x)
{ return __x->_M_singular(); }
/** \brief Safe iterator wrapper.
*
* The class template %_Safe_iterator is a wrapper around an
* iterator that tracks the iterator's movement among sequences and
* checks that operations performed on the "safe" iterator are
* legal. In additional to the basic iterator operations (which are
* validated, and then passed to the underlying iterator),
* %_Safe_iterator has member functions for iterator invalidation,
* attaching/detaching the iterator from sequences, and querying
* the iterator's state.
*/
template
class _Safe_iterator : public _Safe_iterator_base
{
typedef _Safe_iterator _Self;
/** The precision to which we can calculate the distance between
* two iterators.
*/
enum _Distance_precision
{
__dp_equality, //< Can compare iterator equality, only
__dp_sign, //< Can determine equality and ordering
__dp_exact //< Can determine distance precisely
};
/// The underlying iterator
_Iterator _M_current;
/// Determine if this is a constant iterator.
bool
_M_constant() const
{
typedef typename _Sequence::const_iterator const_iterator;
return std::__are_same::__value;
}
typedef std::iterator_traits<_Iterator> _Traits;
public:
typedef _Iterator iterator_type;
typedef typename _Traits::iterator_category iterator_category;
typedef typename _Traits::value_type value_type;
typedef typename _Traits::difference_type difference_type;
typedef typename _Traits::reference reference;
typedef typename _Traits::pointer pointer;
/// @post the iterator is singular and unattached
_Safe_iterator() : _M_current() { }
/**
* @brief Safe iterator construction from an unsafe iterator and
* its sequence.
*
* @pre @p seq is not NULL
* @post this is not singular
*/
_Safe_iterator(const _Iterator& __i, const _Sequence* __seq)
: _Safe_iterator_base(__seq, _M_constant()), _M_current(__i)
{
_GLIBCXX_DEBUG_VERIFY(! this->_M_singular(),
_M_message(__msg_init_singular)
._M_iterator(*this, "this"));
}
/**
* @brief Copy construction.
*/
_Safe_iterator(const _Safe_iterator& __x)
: _Safe_iterator_base(__x, _M_constant()), _M_current(__x._M_current)
{
// _GLIBCXX_RESOLVE_LIB_DEFECTS
// DR 408. Is vector > forbidden?
_GLIBCXX_DEBUG_VERIFY(!__x._M_singular()
|| __x._M_current == _Iterator(),
_M_message(__msg_init_copy_singular)
._M_iterator(*this, "this")
._M_iterator(__x, "other"));
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/**
* @brief Move construction.
* @post __x is singular and unattached
*/
_Safe_iterator(_Safe_iterator&& __x) : _M_current()
{
_GLIBCXX_DEBUG_VERIFY(!__x._M_singular()
|| __x._M_current == _Iterator(),
_M_message(__msg_init_copy_singular)
._M_iterator(*this, "this")
._M_iterator(__x, "other"));
std::swap(_M_current, __x._M_current);
this->_M_attach(__x._M_sequence);
__x._M_detach();
}
#endif
/**
* @brief Converting constructor from a mutable iterator to a
* constant iterator.
*/
template
_Safe_iterator(
const _Safe_iterator<_MutableIterator,
typename __gnu_cxx::__enable_if<(std::__are_same<_MutableIterator,
typename _Sequence::iterator::iterator_type>::__value),
_Sequence>::__type>& __x)
: _Safe_iterator_base(__x, _M_constant()), _M_current(__x.base())
{
// _GLIBCXX_RESOLVE_LIB_DEFECTS
// DR 408. Is vector > forbidden?
_GLIBCXX_DEBUG_VERIFY(!__x._M_singular()
|| __x.base() == _Iterator(),
_M_message(__msg_init_const_singular)
._M_iterator(*this, "this")
._M_iterator(__x, "other"));
}
/**
* @brief Copy assignment.
*/
_Safe_iterator&
operator=(const _Safe_iterator& __x)
{
// _GLIBCXX_RESOLVE_LIB_DEFECTS
// DR 408. Is vector > forbidden?
_GLIBCXX_DEBUG_VERIFY(!__x._M_singular()
|| __x._M_current == _Iterator(),
_M_message(__msg_copy_singular)
._M_iterator(*this, "this")
._M_iterator(__x, "other"));
_M_current = __x._M_current;
this->_M_attach(__x._M_sequence);
return *this;
}
#ifdef __GXX_EXPERIMENTAL_CXX0X__
/**
* @brief Move assignment.
* @post __x is singular and unattached
*/
_Safe_iterator&
operator=(_Safe_iterator&& __x)
{
_GLIBCXX_DEBUG_VERIFY(!__x._M_singular()
|| __x._M_current == _Iterator(),
_M_message(__msg_copy_singular)
._M_iterator(*this, "this")
._M_iterator(__x, "other"));
_M_current = __x._M_current;
_M_attach(__x._M_sequence);
__x._M_detach();
__x._M_current = _Iterator();
return *this;
}
#endif
/**
* @brief Iterator dereference.
* @pre iterator is dereferenceable
*/
reference
operator*() const
{
_GLIBCXX_DEBUG_VERIFY(this->_M_dereferenceable(),
_M_message(__msg_bad_deref)
._M_iterator(*this, "this"));
return *_M_current;
}
/**
* @brief Iterator dereference.
* @pre iterator is dereferenceable
* @todo Make this correct w.r.t. iterators that return proxies
* @todo Use addressof() instead of & operator
*/
pointer
operator->() const
{
_GLIBCXX_DEBUG_VERIFY(this->_M_dereferenceable(),
_M_message(__msg_bad_deref)
._M_iterator(*this, "this"));
return &*_M_current;
}
// ------ Input iterator requirements ------
/**
* @brief Iterator preincrement
* @pre iterator is incrementable
*/
_Safe_iterator&
operator++()
{
_GLIBCXX_DEBUG_VERIFY(this->_M_incrementable(),
_M_message(__msg_bad_inc)
._M_iterator(*this, "this"));
++_M_current;
return *this;
}
/**
* @brief Iterator postincrement
* @pre iterator is incrementable
*/
_Safe_iterator
operator++(int)
{
_GLIBCXX_DEBUG_VERIFY(this->_M_incrementable(),
_M_message(__msg_bad_inc)
._M_iterator(*this, "this"));
_Safe_iterator __tmp(*this);
++_M_current;
return __tmp;
}
// ------ Bidirectional iterator requirements ------
/**
* @brief Iterator predecrement
* @pre iterator is decrementable
*/
_Safe_iterator&
operator--()
{
_GLIBCXX_DEBUG_VERIFY(this->_M_decrementable(),
_M_message(__msg_bad_dec)
._M_iterator(*this, "this"));
--_M_current;
return *this;
}
/**
* @brief Iterator postdecrement
* @pre iterator is decrementable
*/
_Safe_iterator
operator--(int)
{
_GLIBCXX_DEBUG_VERIFY(this->_M_decrementable(),
_M_message(__msg_bad_dec)
._M_iterator(*this, "this"));
_Safe_iterator __tmp(*this);
--_M_current;
return __tmp;
}
// ------ Random access iterator requirements ------
reference
operator[](const difference_type& __n) const
{
_GLIBCXX_DEBUG_VERIFY(this->_M_can_advance(__n)
&& this->_M_can_advance(__n+1),
_M_message(__msg_iter_subscript_oob)
._M_iterator(*this)._M_integer(__n));
return _M_current[__n];
}
_Safe_iterator&
operator+=(const difference_type& __n)
{
_GLIBCXX_DEBUG_VERIFY(this->_M_can_advance(__n),
_M_message(__msg_advance_oob)
._M_iterator(*this)._M_integer(__n));
_M_current += __n;
return *this;
}
_Safe_iterator
operator+(const difference_type& __n) const
{
_Safe_iterator __tmp(*this);
__tmp += __n;
return __tmp;
}
_Safe_iterator&
operator-=(const difference_type& __n)
{
_GLIBCXX_DEBUG_VERIFY(this->_M_can_advance(-__n),
_M_message(__msg_retreat_oob)
._M_iterator(*this)._M_integer(__n));
_M_current += -__n;
return *this;
}
_Safe_iterator
operator-(const difference_type& __n) const
{
_Safe_iterator __tmp(*this);
__tmp -= __n;
return __tmp;
}
// ------ Utilities ------
/**
* @brief Return the underlying iterator
*/
_Iterator
base() const { return _M_current; }
/**
* @brief Conversion to underlying non-debug iterator to allow
* better interaction with non-debug containers.
*/
operator _Iterator() const { return _M_current; }
/** Attach iterator to the given sequence. */
void
_M_attach(_Safe_sequence_base* __seq)
{
_Safe_iterator_base::_M_attach(__seq, _M_constant());
}
/** Likewise, but not thread-safe. */
void
_M_attach_single(_Safe_sequence_base* __seq)
{
_Safe_iterator_base::_M_attach_single(__seq, _M_constant());
}
/// Is the iterator dereferenceable?
bool
_M_dereferenceable() const
{ return !this->_M_singular() && !_M_is_end() && !_M_is_before_begin(); }
/// Is the iterator before a dereferenceable one?
bool
_M_before_dereferenceable() const
{
_Self __it = *this;
return __it._M_incrementable() && (++__it)._M_dereferenceable();
}
/// Is the iterator incrementable?
bool
_M_incrementable() const
{ return !this->_M_singular() && !_M_is_end(); }
// Is the iterator decrementable?
bool
_M_decrementable() const { return !_M_singular() && !_M_is_begin(); }
// Can we advance the iterator @p __n steps (@p __n may be negative)
bool
_M_can_advance(const difference_type& __n) const;
// Is the iterator range [*this, __rhs) valid?
template
bool
_M_valid_range(const _Safe_iterator<_Other, _Sequence>& __rhs) const;
// The sequence this iterator references.
const _Sequence*
_M_get_sequence() const
{ return static_cast(_M_sequence); }
/** Determine the distance between two iterators with some known
* precision.
*/
template
static std::pair
_M_get_distance(const _Iterator1& __lhs, const _Iterator2& __rhs)
{
typedef typename std::iterator_traits<_Iterator1>::iterator_category
_Category;
return _M_get_distance(__lhs, __rhs, _Category());
}
template
static std::pair
_M_get_distance(const _Iterator1& __lhs, const _Iterator2& __rhs,
std::random_access_iterator_tag)
{ return std::make_pair(__rhs - __lhs, __dp_exact); }
template
static std::pair
_M_get_distance(const _Iterator1& __lhs, const _Iterator2& __rhs,
std::forward_iterator_tag)
{ return std::make_pair(__lhs == __rhs? 0 : 1, __dp_equality); }
/// Is this iterator equal to the sequence's begin() iterator?
bool _M_is_begin() const
{ return base() == _M_get_sequence()->_M_base().begin(); }
/// Is this iterator equal to the sequence's end() iterator?
bool _M_is_end() const
{ return base() == _M_get_sequence()->_M_base().end(); }
/// Is this iterator equal to the sequence's before_begin() iterator if
/// any?
bool _M_is_before_begin() const
{
return _BeforeBeginHelper<_Sequence>::_M_Is(base(), _M_get_sequence());
}
};
template
inline bool
operator==(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_compare_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_compare_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() == __rhs.base();
}
template
inline bool
operator==(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_compare_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_compare_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() == __rhs.base();
}
template
inline bool
operator!=(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_compare_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_compare_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() != __rhs.base();
}
template
inline bool
operator!=(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_compare_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_compare_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() != __rhs.base();
}
template
inline bool
operator<(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() < __rhs.base();
}
template
inline bool
operator<(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() < __rhs.base();
}
template
inline bool
operator<=(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() <= __rhs.base();
}
template
inline bool
operator<=(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() <= __rhs.base();
}
template
inline bool
operator>(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() > __rhs.base();
}
template
inline bool
operator>(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() > __rhs.base();
}
template
inline bool
operator>=(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() >= __rhs.base();
}
template
inline bool
operator>=(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_iter_order_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_order_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() >= __rhs.base();
}
// _GLIBCXX_RESOLVE_LIB_DEFECTS
// According to the resolution of DR179 not only the various comparison
// operators but also operator- must accept mixed iterator/const_iterator
// parameters.
template
inline typename _Safe_iterator<_IteratorL, _Sequence>::difference_type
operator-(const _Safe_iterator<_IteratorL, _Sequence>& __lhs,
const _Safe_iterator<_IteratorR, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_distance_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_distance_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() - __rhs.base();
}
template
inline typename _Safe_iterator<_Iterator, _Sequence>::difference_type
operator-(const _Safe_iterator<_Iterator, _Sequence>& __lhs,
const _Safe_iterator<_Iterator, _Sequence>& __rhs)
{
_GLIBCXX_DEBUG_VERIFY(! __lhs._M_singular() && ! __rhs._M_singular(),
_M_message(__msg_distance_bad)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
_GLIBCXX_DEBUG_VERIFY(__lhs._M_can_compare(__rhs),
_M_message(__msg_distance_different)
._M_iterator(__lhs, "lhs")
._M_iterator(__rhs, "rhs"));
return __lhs.base() - __rhs.base();
}
template
inline _Safe_iterator<_Iterator, _Sequence>
operator+(typename _Safe_iterator<_Iterator,_Sequence>::difference_type __n,
const _Safe_iterator<_Iterator, _Sequence>& __i)
{ return __i + __n; }
// Helper struct to detect random access safe iterators.
template
struct __is_safe_random_iterator
{
enum { __value = 0 };
typedef std::__false_type __type;
};
template
struct __is_safe_random_iterator<_Safe_iterator<_Iterator, _Sequence> >
: std::__are_same::
iterator_category>
{ };
template
struct _Siter_base
: std::_Iter_base<_Iterator, __is_safe_random_iterator<_Iterator>::__value>
{ };
/** Helper function to extract base iterator of random access safe iterator
in order to reduce performance impact of debug mode. Limited to random
access iterator because it is the only category for which it is possible
to check for correct iterators order in the __valid_range function
thanks to the < operator.
*/
template
inline typename _Siter_base<_Iterator>::iterator_type
__base(_Iterator __it)
{ return _Siter_base<_Iterator>::_S_base(__it); }
} // namespace __gnu_debug
#include
#endif