boost/xpressive/regex_iterator.hpp
///////////////////////////////////////////////////////////////////////////////
/// \file regex_iterator.hpp
/// Contains the definition of the regex_iterator type, an STL-compatible iterator
/// for stepping through all the matches in a sequence.
//
// Copyright 2004 Eric Niebler. Distributed under the Boost
// Software License, Version 1.0. (See accompanying file
// LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
#ifndef BOOST_XPRESSIVE_REGEX_ITERATOR_HPP_EAN_10_04_2005
#define BOOST_XPRESSIVE_REGEX_ITERATOR_HPP_EAN_10_04_2005
// MS compatible compilers support #pragma once
#if defined(_MSC_VER) && (_MSC_VER >= 1020)
# pragma once
#endif
#include <boost/noncopyable.hpp>
#include <boost/iterator/iterator_traits.hpp>
#include <boost/xpressive/detail/detail_fwd.hpp>
#include <boost/xpressive/detail/core/access.hpp>
namespace boost { namespace xpressive { namespace detail
{
//////////////////////////////////////////////////////////////////////////
// regex_iterator_impl
//
template<typename BidiIter>
struct regex_iterator_impl
: private noncopyable
{
typedef detail::core_access<BidiIter> access;
regex_iterator_impl
(
BidiIter begin
, BidiIter cur
, BidiIter end
, basic_regex<BidiIter> const *rex
, regex_constants::match_flag_type flags
, bool not_null = false
)
: what_()
, state_(begin, end, what_, *access::get_regex_impl(*rex), flags)
, rex_(rex)
, flags_(flags)
, not_null_(not_null)
{
this->state_.cur_ = cur;
}
bool next()
{
this->state_.reset(this->what_, *access::get_regex_impl(*this->rex_));
if(!regex_search_impl(this->state_, *this->rex_, this->not_null_))
{
return false;
}
// Report position() correctly by setting the base different from prefix().first
access::set_base(this->what_, this->state_.begin_);
this->state_.cur_ = this->what_[0].second;
this->not_null_ = (0 == this->what_.length());
return true;
}
bool equal_to(regex_iterator_impl<BidiIter> const &that) const
{
return this->rex_ == that.rex_
&& this->state_.begin_ == that.state_.begin_
&& this->state_.cur_ == that.state_.cur_
&& this->state_.end_ == that.state_.end_
&& this->flags_ == that.flags_
;
}
match_results<BidiIter> what_;
state_type<BidiIter> state_;
basic_regex<BidiIter> const *const rex_;
regex_constants::match_flag_type const flags_;
bool not_null_;
};
} // namespace detail
//////////////////////////////////////////////////////////////////////////
// regex_iterator
//
template<typename BidiIter>
struct regex_iterator
{
typedef basic_regex<BidiIter> regex_type;
typedef match_results<BidiIter> value_type;
typedef typename iterator_difference<BidiIter>::type difference_type;
typedef value_type const *pointer;
typedef value_type const &reference;
typedef std::forward_iterator_tag iterator_category;
/// INTERNAL ONLY
typedef detail::regex_iterator_impl<BidiIter> impl_type_;
regex_iterator()
: impl_()
{
}
regex_iterator
(
BidiIter begin
, BidiIter end
, basic_regex<BidiIter> const &rex
, regex_constants::match_flag_type flags = regex_constants::match_default
)
: impl_(new impl_type_(begin, begin, end, &rex, flags))
{
this->next_();
}
regex_iterator(regex_iterator<BidiIter> const &that)
: impl_(that.impl_) // COW
{
}
regex_iterator<BidiIter> &operator =(regex_iterator<BidiIter> const &that)
{
this->impl_ = that.impl_; // COW
return *this;
}
friend bool operator ==(regex_iterator<BidiIter> const &left, regex_iterator<BidiIter> const &right)
{
if(!left.impl_ || !right.impl_)
{
return !left.impl_ && !right.impl_;
}
return left.impl_->equal_to(*right.impl_);
}
friend bool operator !=(regex_iterator<BidiIter> const &left, regex_iterator<BidiIter> const &right)
{
return !(left == right);
}
value_type const &operator *() const
{
return this->impl_->what_;
}
value_type const *operator ->() const
{
return &this->impl_->what_;
}
/// If what.prefix().first != what[0].second and if the element match_prev_avail is not set in
/// flags then sets it. Then behaves as if by calling regex_search(what[0].second, end, what, *pre, flags),
/// with the following variation: in the event that the previous match found was of zero length
/// (what[0].length() == 0) then attempts to find a non-zero length match starting at what[0].second,
/// only if that fails and provided what[0].second != suffix().second does it look for a (possibly
/// zero length) match starting from what[0].second + 1. If no further match is found then sets
/// *this equal to the end of sequence iterator.
/// \post (*this)-\>size() == pre-\>mark_count()
/// \post (*this)-\>empty() == false
/// \post (*this)-\>prefix().first == An iterator denoting the end point of the previous match found
/// \post (*this)-\>prefix().last == (**this)[0].first
/// \post (*this)-\>prefix().matched == (*this)-\>prefix().first != (*this)-\>prefix().second
/// \post (*this)-\>suffix().first == (**this)[0].second
/// \post (*this)-\>suffix().last == end
/// \post (*this)-\>suffix().matched == (*this)-\>suffix().first != (*this)-\>suffix().second
/// \post (**this)[0].first == The starting iterator for this match.
/// \post (**this)[0].second == The ending iterator for this match.
/// \post (**this)[0].matched == true if a full match was found, and false if it was a partial match (found as a result of the match_partial flag being set).
/// \post (**this)[n].first == For all integers n \< (*this)-\>size(), the start of the sequence that matched sub-expression n. Alternatively, if sub-expression n did not participate in the match, then end.
/// \post (**this)[n].second == For all integers n \< (*this)-\>size(), the end of the sequence that matched sub-expression n. Alternatively, if sub-expression n did not participate in the match, then end.
/// \post (**this)[n].matched == For all integers n \< (*this)-\>size(), true if sub-expression n participated in the match, false otherwise.
/// \post (*this)-\>position() == The distance from the start of the original sequence being iterated, to the start of this match.
regex_iterator<BidiIter> &operator ++()
{
this->fork_(); // un-share the implementation
this->next_();
return *this;
}
regex_iterator<BidiIter> operator ++(int)
{
regex_iterator<BidiIter> tmp(*this);
++*this;
return tmp;
}
private:
/// INTERNAL ONLY
void fork_()
{
if(!this->impl_.unique())
{
this->impl_.reset
(
new impl_type_
(
this->impl_->state_.begin_
, this->impl_->state_.cur_
, this->impl_->state_.end_
, this->impl_->rex_
, this->impl_->flags_
, this->impl_->not_null_
)
);
}
}
/// INTERNAL ONLY
void next_()
{
BOOST_ASSERT(this->impl_ && this->impl_.unique());
if(!this->impl_->next())
{
this->impl_.reset();
}
}
shared_ptr<impl_type_> impl_;
};
}} // namespace boost::xpressive
#endif