// class template regex -*- C++ -*-
// Copyright (C) 2013-2015 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 bits/regex.tcc
* This is an internal header file, included by other library headers.
* Do not attempt to use it directly. @headername{regex}
*/
// A non-standard switch to let the user pick the matching algorithm.
// If _GLIBCXX_REGEX_USE_THOMPSON_NFA is defined, the thompson NFA
// algorithm will be used. This algorithm is not enabled by default,
// and cannot be used if the regex contains back-references, but has better
// (polynomial instead of exponential) worst case performance.
// See __regex_algo_impl below.
namespace std _GLIBCXX_VISIBILITY(default)
{
namespace __detail
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
// Result of merging regex_match and regex_search.
//
// __policy now can be _S_auto (auto dispatch) and _S_alternate (use
// the other one if possible, for test purpose).
//
// That __match_mode is true means regex_match, else regex_search.
template
bool
__regex_algo_impl(_BiIter __s,
_BiIter __e,
match_results<_BiIter, _Alloc>& __m,
const basic_regex<_CharT, _TraitsT>& __re,
regex_constants::match_flag_type __flags)
{
if (__re._M_automaton == nullptr)
return false;
typename match_results<_BiIter, _Alloc>::_Base_type& __res = __m;
__m._M_begin = __s;
__res.resize(__re._M_automaton->_M_sub_count() + 2);
for (auto& __it : __res)
__it.matched = false;
// __policy is used by testsuites so that they can use Thompson NFA
// without defining a macro. Users should define
// _GLIBCXX_REGEX_USE_THOMPSON_NFA if they need to use this approach.
bool __ret;
if (!__re._M_automaton->_M_has_backref
&& !(__re._M_flags & regex_constants::ECMAScript)
#ifndef _GLIBCXX_REGEX_USE_THOMPSON_NFA
&& __policy == _RegexExecutorPolicy::_S_alternate
#endif
)
{
_Executor<_BiIter, _Alloc, _TraitsT, false>
__executor(__s, __e, __m, __re, __flags);
if (__match_mode)
__ret = __executor._M_match();
else
__ret = __executor._M_search();
}
else
{
_Executor<_BiIter, _Alloc, _TraitsT, true>
__executor(__s, __e, __m, __re, __flags);
if (__match_mode)
__ret = __executor._M_match();
else
__ret = __executor._M_search();
}
if (__ret)
{
for (auto& __it : __res)
if (!__it.matched)
__it.first = __it.second = __e;
auto& __pre = __res[__res.size()-2];
auto& __suf = __res[__res.size()-1];
if (__match_mode)
{
__pre.matched = false;
__pre.first = __s;
__pre.second = __s;
__suf.matched = false;
__suf.first = __e;
__suf.second = __e;
}
else
{
__pre.first = __s;
__pre.second = __res[0].first;
__pre.matched = (__pre.first != __pre.second);
__suf.first = __res[0].second;
__suf.second = __e;
__suf.matched = (__suf.first != __suf.second);
}
}
return __ret;
}
_GLIBCXX_END_NAMESPACE_VERSION
}
_GLIBCXX_BEGIN_NAMESPACE_VERSION
template
template
typename regex_traits<_Ch_type>::string_type
regex_traits<_Ch_type>::
lookup_collatename(_Fwd_iter __first, _Fwd_iter __last) const
{
typedef std::ctype __ctype_type;
const __ctype_type& __fctyp(use_facet<__ctype_type>(_M_locale));
static const char* __collatenames[] =
{
"NUL",
"SOH",
"STX",
"ETX",
"EOT",
"ENQ",
"ACK",
"alert",
"backspace",
"tab",
"newline",
"vertical-tab",
"form-feed",
"carriage-return",
"SO",
"SI",
"DLE",
"DC1",
"DC2",
"DC3",
"DC4",
"NAK",
"SYN",
"ETB",
"CAN",
"EM",
"SUB",
"ESC",
"IS4",
"IS3",
"IS2",
"IS1",
"space",
"exclamation-mark",
"quotation-mark",
"number-sign",
"dollar-sign",
"percent-sign",
"ampersand",
"apostrophe",
"left-parenthesis",
"right-parenthesis",
"asterisk",
"plus-sign",
"comma",
"hyphen",
"period",
"slash",
"zero",
"one",
"two",
"three",
"four",
"five",
"six",
"seven",
"eight",
"nine",
"colon",
"semicolon",
"less-than-sign",
"equals-sign",
"greater-than-sign",
"question-mark",
"commercial-at",
"A",
"B",
"C",
"D",
"E",
"F",
"G",
"H",
"I",
"J",
"K",
"L",
"M",
"N",
"O",
"P",
"Q",
"R",
"S",
"T",
"U",
"V",
"W",
"X",
"Y",
"Z",
"left-square-bracket",
"backslash",
"right-square-bracket",
"circumflex",
"underscore",
"grave-accent",
"a",
"b",
"c",
"d",
"e",
"f",
"g",
"h",
"i",
"j",
"k",
"l",
"m",
"n",
"o",
"p",
"q",
"r",
"s",
"t",
"u",
"v",
"w",
"x",
"y",
"z",
"left-curly-bracket",
"vertical-line",
"right-curly-bracket",
"tilde",
"DEL",
""
};
// same as boost
//static const char* __digraphs[] =
// {
// "ae",
// "Ae",
// "AE",
// "ch",
// "Ch",
// "CH",
// "ll",
// "Ll",
// "LL",
// "ss",
// "Ss",
// "SS",
// "nj",
// "Nj",
// "NJ",
// "dz",
// "Dz",
// "DZ",
// "lj",
// "Lj",
// "LJ",
// ""
// };
std::string __s(__last - __first, '?');
__fctyp.narrow(__first, __last, '?', &*__s.begin());
for (unsigned int __i = 0; *__collatenames[__i]; __i++)
if (__s == __collatenames[__i])
return string_type(1, __fctyp.widen(static_cast(__i)));
//for (unsigned int __i = 0; *__digraphs[__i]; __i++)
// {
// const char* __now = __digraphs[__i];
// if (__s == __now)
// {
// string_type ret(__s.size(), __fctyp.widen('?'));
// __fctyp.widen(__now, __now + 2/* ouch */, &*ret.begin());
// return ret;
// }
// }
return string_type();
}
template
template
typename regex_traits<_Ch_type>::char_class_type
regex_traits<_Ch_type>::
lookup_classname(_Fwd_iter __first, _Fwd_iter __last, bool __icase) const
{
typedef std::ctype __ctype_type;
typedef std::ctype __cctype_type;
typedef const pair _ClassnameEntry;
const __ctype_type& __fctyp(use_facet<__ctype_type>(_M_locale));
const __cctype_type& __cctyp(use_facet<__cctype_type>(_M_locale));
static _ClassnameEntry __classnames[] =
{
{"d", ctype_base::digit},
{"w", {ctype_base::alnum, _RegexMask::_S_under}},
{"s", ctype_base::space},
{"alnum", ctype_base::alnum},
{"alpha", ctype_base::alpha},
{"blank", ctype_base::blank},
{"cntrl", ctype_base::cntrl},
{"digit", ctype_base::digit},
{"graph", ctype_base::graph},
{"lower", ctype_base::lower},
{"print", ctype_base::print},
{"punct", ctype_base::punct},
{"space", ctype_base::space},
{"upper", ctype_base::upper},
{"xdigit", ctype_base::xdigit},
};
std::string __s(__last - __first, '?');
__fctyp.narrow(__first, __last, '?', &__s[0]);
__cctyp.tolower(&*__s.begin(), &*__s.begin() + __s.size());
for (_ClassnameEntry* __it = __classnames;
__it < *(&__classnames + 1);
++__it)
{
if (__s == __it->first)
{
if (__icase
&& ((__it->second
& (ctype_base::lower | ctype_base::upper)) != 0))
return ctype_base::alpha;
return __it->second;
}
}
return 0;
}
template
bool
regex_traits<_Ch_type>::
isctype(_Ch_type __c, char_class_type __f) const
{
typedef std::ctype __ctype_type;
const __ctype_type& __fctyp(use_facet<__ctype_type>(_M_locale));
return __fctyp.is(__f._M_base, __c)
// [[:w:]]
|| ((__f._M_extended & _RegexMask::_S_under)
&& __c == __fctyp.widen('_'));
}
template
int
regex_traits<_Ch_type>::
value(_Ch_type __ch, int __radix) const
{
std::basic_istringstream __is(string_type(1, __ch));
long __v;
if (__radix == 8)
__is >> std::oct;
else if (__radix == 16)
__is >> std::hex;
__is >> __v;
return __is.fail() ? -1 : __v;
}
template
template
_Out_iter match_results<_Bi_iter, _Alloc>::
format(_Out_iter __out,
const match_results<_Bi_iter, _Alloc>::char_type* __fmt_first,
const match_results<_Bi_iter, _Alloc>::char_type* __fmt_last,
match_flag_type __flags) const
{
_GLIBCXX_DEBUG_ASSERT( ready() );
regex_traits __traits;
typedef std::ctype __ctype_type;
const __ctype_type&
__fctyp(use_facet<__ctype_type>(__traits.getloc()));
auto __output = [&](size_t __idx)
{
auto& __sub = _Base_type::operator[](__idx);
if (__sub.matched)
__out = std::copy(__sub.first, __sub.second, __out);
};
if (__flags & regex_constants::format_sed)
{
for (; __fmt_first != __fmt_last;)
if (*__fmt_first == '&')
{
__output(0);
++__fmt_first;
}
else if (*__fmt_first == '\\')
{
if (++__fmt_first != __fmt_last
&& __fctyp.is(__ctype_type::digit, *__fmt_first))
__output(__traits.value(*__fmt_first++, 10));
else
*__out++ = '\\';
}
else
*__out++ = *__fmt_first++;
}
else
{
while (1)
{
auto __next = std::find(__fmt_first, __fmt_last, '$');
if (__next == __fmt_last)
break;
__out = std::copy(__fmt_first, __next, __out);
auto __eat = [&](char __ch) -> bool
{
if (*__next == __ch)
{
++__next;
return true;
}
return false;
};
if (++__next == __fmt_last)
*__out++ = '$';
else if (__eat('$'))
*__out++ = '$';
else if (__eat('&'))
__output(0);
else if (__eat('`'))
__output(_Base_type::size()-2);
else if (__eat('\''))
__output(_Base_type::size()-1);
else if (__fctyp.is(__ctype_type::digit, *__next))
{
long __num = __traits.value(*__next, 10);
if (++__next != __fmt_last
&& __fctyp.is(__ctype_type::digit, *__next))
{
__num *= 10;
__num += __traits.value(*__next++, 10);
}
if (0 <= __num && __num < this->size())
__output(__num);
}
else
*__out++ = '$';
__fmt_first = __next;
}
__out = std::copy(__fmt_first, __fmt_last, __out);
}
return __out;
}
template
_Out_iter
regex_replace(_Out_iter __out, _Bi_iter __first, _Bi_iter __last,
const basic_regex<_Ch_type, _Rx_traits>& __e,
const _Ch_type* __fmt,
regex_constants::match_flag_type __flags)
{
typedef regex_iterator<_Bi_iter, _Ch_type, _Rx_traits> _IterT;
_IterT __i(__first, __last, __e, __flags);
_IterT __end;
if (__i == __end)
{
if (!(__flags & regex_constants::format_no_copy))
__out = std::copy(__first, __last, __out);
}
else
{
sub_match<_Bi_iter> __last;
auto __len = char_traits<_Ch_type>::length(__fmt);
for (; __i != __end; ++__i)
{
if (!(__flags & regex_constants::format_no_copy))
__out = std::copy(__i->prefix().first, __i->prefix().second,
__out);
__out = __i->format(__out, __fmt, __fmt + __len, __flags);
__last = __i->suffix();
if (__flags & regex_constants::format_first_only)
break;
}
if (!(__flags & regex_constants::format_no_copy))
__out = std::copy(__last.first, __last.second, __out);
}
return __out;
}
template
bool
regex_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
operator==(const regex_iterator& __rhs) const
{
return (_M_match.empty() && __rhs._M_match.empty())
|| (_M_begin == __rhs._M_begin
&& _M_end == __rhs._M_end
&& _M_pregex == __rhs._M_pregex
&& _M_flags == __rhs._M_flags
&& _M_match[0] == __rhs._M_match[0]);
}
template
regex_iterator<_Bi_iter, _Ch_type, _Rx_traits>&
regex_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
operator++()
{
// In all cases in which the call to regex_search returns true,
// match.prefix().first shall be equal to the previous value of
// match[0].second, and for each index i in the half-open range
// [0, match.size()) for which match[i].matched is true,
// match[i].position() shall return distance(begin, match[i].first).
// [28.12.1.4.5]
if (_M_match[0].matched)
{
auto __start = _M_match[0].second;
auto __prefix_first = _M_match[0].second;
if (_M_match[0].first == _M_match[0].second)
{
if (__start == _M_end)
{
_M_match = value_type();
return *this;
}
else
{
if (regex_search(__start, _M_end, _M_match, *_M_pregex,
_M_flags
| regex_constants::match_not_null
| regex_constants::match_continuous))
{
_GLIBCXX_DEBUG_ASSERT(_M_match[0].matched);
auto& __prefix = _M_match.at(_M_match.size());
__prefix.first = __prefix_first;
__prefix.matched = __prefix.first != __prefix.second;
// [28.12.1.4.5]
_M_match._M_begin = _M_begin;
return *this;
}
else
++__start;
}
}
_M_flags |= regex_constants::match_prev_avail;
if (regex_search(__start, _M_end, _M_match, *_M_pregex, _M_flags))
{
_GLIBCXX_DEBUG_ASSERT(_M_match[0].matched);
auto& __prefix = _M_match.at(_M_match.size());
__prefix.first = __prefix_first;
__prefix.matched = __prefix.first != __prefix.second;
// [28.12.1.4.5]
_M_match._M_begin = _M_begin;
}
else
_M_match = value_type();
}
return *this;
}
template
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>&
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
operator=(const regex_token_iterator& __rhs)
{
_M_position = __rhs._M_position;
_M_subs = __rhs._M_subs;
_M_n = __rhs._M_n;
_M_suffix = __rhs._M_suffix;
_M_has_m1 = __rhs._M_has_m1;
_M_normalize_result();
return *this;
}
template
bool
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
operator==(const regex_token_iterator& __rhs) const
{
if (_M_end_of_seq() && __rhs._M_end_of_seq())
return true;
if (_M_suffix.matched && __rhs._M_suffix.matched
&& _M_suffix == __rhs._M_suffix)
return true;
if (_M_end_of_seq() || _M_suffix.matched
|| __rhs._M_end_of_seq() || __rhs._M_suffix.matched)
return false;
return _M_position == __rhs._M_position
&& _M_n == __rhs._M_n
&& _M_subs == __rhs._M_subs;
}
template
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>&
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
operator++()
{
_Position __prev = _M_position;
if (_M_suffix.matched)
*this = regex_token_iterator();
else if (_M_n + 1 < _M_subs.size())
{
_M_n++;
_M_result = &_M_current_match();
}
else
{
_M_n = 0;
++_M_position;
if (_M_position != _Position())
_M_result = &_M_current_match();
else if (_M_has_m1 && __prev->suffix().length() != 0)
{
_M_suffix.matched = true;
_M_suffix.first = __prev->suffix().first;
_M_suffix.second = __prev->suffix().second;
_M_result = &_M_suffix;
}
else
*this = regex_token_iterator();
}
return *this;
}
template
void
regex_token_iterator<_Bi_iter, _Ch_type, _Rx_traits>::
_M_init(_Bi_iter __a, _Bi_iter __b)
{
_M_has_m1 = false;
for (auto __it : _M_subs)
if (__it == -1)
{
_M_has_m1 = true;
break;
}
if (_M_position != _Position())
_M_result = &_M_current_match();
else if (_M_has_m1)
{
_M_suffix.matched = true;
_M_suffix.first = __a;
_M_suffix.second = __b;
_M_result = &_M_suffix;
}
else
_M_result = nullptr;
}
_GLIBCXX_END_NAMESPACE_VERSION
} // namespace