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// string_token.hpp
// Copyright (c) 2007-2009 Ben Hanson (http://www.benhanson.net/)
//
// Distributed under the Boost Software License, Version 1.0. (See accompanying
// file licence_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
#ifndef BOOST_LEXER_STRING_TOKEN_HPP
#define BOOST_LEXER_STRING_TOKEN_HPP
#include <algorithm>
#include "size_t.hpp"
#include "consts.hpp" // num_chars, num_wchar_ts
#include <string>
#include <limits>
namespace boost
{
namespace lexer
{
template<typename CharT>
struct basic_string_token
{
typedef std::basic_string<CharT> string;
bool _negated;
string _charset;
basic_string_token () :
_negated (false)
{
}
basic_string_token (const bool negated_, const string &charset_) :
_negated (negated_),
_charset (charset_)
{
}
void remove_duplicates ()
{
const CharT *start_ = _charset.c_str ();
const CharT *end_ = start_ + _charset.size ();
// Optimisation for very large charsets:
// sorting via pointers is much quicker than
// via iterators...
std::sort (const_cast<CharT *> (start_), const_cast<CharT *> (end_));
_charset.erase (std::unique (_charset.begin (), _charset.end ()),
_charset.end ());
}
void normalise ()
{
const std::size_t max_chars_ = sizeof (CharT) == 1 ?
num_chars : num_wchar_ts;
if (_charset.length () == max_chars_)
{
_negated = !_negated;
#if defined _MSC_VER && _MSC_VER <= 1200
_charset.erase ();
#else
_charset.clear ();
#endif
}
else if (_charset.length () > max_chars_ / 2)
{
negate ();
}
}
void negate ()
{
const std::size_t max_chars_ = sizeof (CharT) == 1 ?
num_chars : num_wchar_ts;
CharT curr_char_ = (std::numeric_limits<CharT>::min)();
string temp_;
const CharT *curr_ = _charset.c_str ();
const CharT *chars_end_ = curr_ + _charset.size ();
_negated = !_negated;
temp_.resize (max_chars_ - _charset.size ());
CharT *ptr_ = const_cast<CharT *> (temp_.c_str ());
std::size_t i_ = 0;
while (curr_ < chars_end_)
{
while (*curr_ > curr_char_)
{
*ptr_ = curr_char_;
++ptr_;
++curr_char_;
++i_;
}
++curr_char_;
++curr_;
++i_;
}
for (; i_ < max_chars_; ++i_)
{
*ptr_ = curr_char_;
++ptr_;
++curr_char_;
}
_charset = temp_;
}
bool operator < (const basic_string_token &rhs_) const
{
return _negated < rhs_._negated ||
(_negated == rhs_._negated && _charset < rhs_._charset);
}
bool empty () const
{
return _charset.empty () && !_negated;
}
bool any () const
{
return _charset.empty () && _negated;
}
void clear ()
{
_negated = false;
#if defined _MSC_VER && _MSC_VER <= 1200
_charset.erase ();
#else
_charset.clear ();
#endif
}
void intersect (basic_string_token &rhs_, basic_string_token &overlap_)
{
if ((any () && rhs_.any ()) || (_negated == rhs_._negated &&
!any () && !rhs_.any ()))
{
intersect_same_types (rhs_, overlap_);
}
else
{
intersect_diff_types (rhs_, overlap_);
}
}
static void escape_char (const CharT ch_, string &out_)
{
switch (ch_)
{
case '\0':
out_ += '\\';
out_ += '0';
break;
case '\a':
out_ += '\\';
out_ += 'a';
break;
case '\b':
out_ += '\\';
out_ += 'b';
break;
case 27:
out_ += '\\';
out_ += 'x';
out_ += '1';
out_ += 'b';
break;
case '\f':
out_ += '\\';
out_ += 'f';
break;
case '\n':
out_ += '\\';
out_ += 'n';
break;
case '\r':
out_ += '\\';
out_ += 'r';
break;
case '\t':
out_ += '\\';
out_ += 't';
break;
case '\v':
out_ += '\\';
out_ += 'v';
break;
case '\\':
out_ += '\\';
out_ += '\\';
break;
case '"':
out_ += '\\';
out_ += '"';
break;
case '\'':
out_ += '\\';
out_ += '\'';
break;
default:
{
if (ch_ < 32 && ch_ >= 0)
{
std::basic_stringstream<CharT> ss_;
out_ += '\\';
out_ += 'x';
ss_ << std::hex <<
static_cast<std::size_t> (ch_);
out_ += ss_.str ();
}
else
{
out_ += ch_;
}
break;
}
}
}
private:
void intersect_same_types (basic_string_token &rhs_,
basic_string_token &overlap_)
{
if (any ())
{
clear ();
overlap_._negated = true;
rhs_.clear ();
}
else
{
typename string::iterator iter_ = _charset.begin ();
typename string::iterator end_ = _charset.end ();
typename string::iterator rhs_iter_ = rhs_._charset.begin ();
typename string::iterator rhs_end_ = rhs_._charset.end ();
overlap_._negated = _negated;
while (iter_ != end_ && rhs_iter_ != rhs_end_)
{
if (*iter_ < *rhs_iter_)
{
++iter_;
}
else if (*iter_ > *rhs_iter_)
{
++rhs_iter_;
}
else
{
overlap_._charset += *iter_;
iter_ = _charset.erase (iter_);
end_ = _charset.end ();
rhs_iter_ = rhs_._charset.erase (rhs_iter_);
rhs_end_ = rhs_._charset.end ();
}
}
if (_negated)
{
// duplicates already merged, so safe to merge
// using std lib.
// src, dest
merge (_charset, overlap_._charset);
// duplicates already merged, so safe to merge
// using std lib.
// src, dest
merge (rhs_._charset, overlap_._charset);
_negated = false;
rhs_._negated = false;
std::swap (_charset, rhs_._charset);
normalise ();
overlap_.normalise ();
rhs_.normalise ();
}
else if (!overlap_._charset.empty ())
{
normalise ();
overlap_.normalise ();
rhs_.normalise ();
}
}
}
void intersect_diff_types (basic_string_token &rhs_,
basic_string_token &overlap_)
{
if (any ())
{
intersect_any (rhs_, overlap_);
}
else if (_negated)
{
intersect_negated (rhs_, overlap_);
}
else // _negated == false
{
intersect_charset (rhs_, overlap_);
}
}
void intersect_any (basic_string_token &rhs_, basic_string_token &overlap_)
{
if (rhs_._negated)
{
rhs_.intersect_negated (*this, overlap_);
}
else // rhs._negated == false
{
rhs_.intersect_charset (*this, overlap_);
}
}
void intersect_negated (basic_string_token &rhs_,
basic_string_token &overlap_)
{
if (rhs_.any ())
{
overlap_._negated = true;
overlap_._charset = _charset;
rhs_._negated = false;
rhs_._charset = _charset;
clear ();
}
else // rhs._negated == false
{
rhs_.intersect_charset (*this, overlap_);
}
}
void intersect_charset (basic_string_token &rhs_,
basic_string_token &overlap_)
{
if (rhs_.any ())
{
overlap_._charset = _charset;
rhs_._negated = true;
rhs_._charset = _charset;
clear ();
}
else // rhs_._negated == true
{
typename string::iterator iter_ = _charset.begin ();
typename string::iterator end_ = _charset.end ();
typename string::iterator rhs_iter_ = rhs_._charset.begin ();
typename string::iterator rhs_end_ = rhs_._charset.end ();
while (iter_ != end_ && rhs_iter_ != rhs_end_)
{
if (*iter_ < *rhs_iter_)
{
overlap_._charset += *iter_;
rhs_iter_ = rhs_._charset.insert (rhs_iter_, *iter_);
++rhs_iter_;
rhs_end_ = rhs_._charset.end ();
iter_ = _charset.erase (iter_);
end_ = _charset.end ();
}
else if (*iter_ > *rhs_iter_)
{
++rhs_iter_;
}
else
{
++iter_;
++rhs_iter_;
}
}
if (iter_ != end_)
{
// nothing bigger in rhs_ than iter_,
// so safe to merge using std lib.
string temp_ (iter_, end_);
// src, dest
merge (temp_, overlap_._charset);
_charset.erase (iter_, end_);
}
if (!overlap_._charset.empty ())
{
merge (overlap_._charset, rhs_._charset);
// possible duplicates, so check for any and erase.
rhs_._charset.erase (std::unique (rhs_._charset.begin (),
rhs_._charset.end ()), rhs_._charset.end ());
normalise ();
overlap_.normalise ();
rhs_.normalise ();
}
}
}
void merge (string &src_, string &dest_)
{
string tmp_ (src_.size () + dest_.size (), 0);
std::merge (src_.begin (), src_.end (), dest_.begin (), dest_.end (),
tmp_.begin ());
dest_ = tmp_;
}
};
}
}
#endif