Retro68/gcc/libstdc++-v3/include/bits/regex_automaton.h

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// class template regex -*- C++ -*-
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// Copyright (C) 2013-2015 Free Software Foundation, Inc.
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//
// 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
// <http://www.gnu.org/licenses/>.
/**
* @file bits/regex_automaton.h
* This is an internal header file, included by other library headers.
* Do not attempt to use it directly. @headername{regex}
*/
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// This macro defines the maximal state number a NFA can have.
#ifndef _GLIBCXX_REGEX_STATE_LIMIT
#define _GLIBCXX_REGEX_STATE_LIMIT 100000
#endif
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namespace std _GLIBCXX_VISIBILITY(default)
{
namespace __detail
{
_GLIBCXX_BEGIN_NAMESPACE_VERSION
/**
* @defgroup regex-detail Base and Implementation Classes
* @ingroup regex
* @{
*/
typedef long _StateIdT;
static const _StateIdT _S_invalid_state_id = -1;
template<typename _CharT>
using _Matcher = std::function<bool (_CharT)>;
/// Operation codes that define the type of transitions within the base NFA
/// that represents the regular expression.
enum _Opcode : int
{
_S_opcode_unknown,
_S_opcode_alternative,
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_S_opcode_repeat,
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_S_opcode_backref,
_S_opcode_line_begin_assertion,
_S_opcode_line_end_assertion,
_S_opcode_word_boundary,
_S_opcode_subexpr_lookahead,
_S_opcode_subexpr_begin,
_S_opcode_subexpr_end,
_S_opcode_dummy,
_S_opcode_match,
_S_opcode_accept,
};
struct _State_base
{
_Opcode _M_opcode; // type of outgoing transition
_StateIdT _M_next; // outgoing transition
union // Since they are mutually exclusive.
{
size_t _M_subexpr; // for _S_opcode_subexpr_*
size_t _M_backref_index; // for _S_opcode_backref
struct
{
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// for _S_opcode_alternative, _S_opcode_repeat and
// _S_opcode_subexpr_lookahead
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_StateIdT _M_alt;
// for _S_opcode_word_boundary or _S_opcode_subexpr_lookahead or
// quantifiers (ungreedy if set true)
bool _M_neg;
};
};
explicit _State_base(_Opcode __opcode)
: _M_opcode(__opcode), _M_next(_S_invalid_state_id)
{ }
protected:
~_State_base() = default;
public:
#ifdef _GLIBCXX_DEBUG
std::ostream&
_M_print(std::ostream& ostr) const;
// Prints graphviz dot commands for state.
std::ostream&
_M_dot(std::ostream& __ostr, _StateIdT __id) const;
#endif
};
template<typename _TraitsT>
struct _State : _State_base
{
typedef _Matcher<typename _TraitsT::char_type> _MatcherT;
_MatcherT _M_matches; // for _S_opcode_match
explicit _State(_Opcode __opcode) : _State_base(__opcode) { }
};
struct _NFA_base
{
typedef size_t _SizeT;
typedef regex_constants::syntax_option_type _FlagT;
explicit
_NFA_base(_FlagT __f)
: _M_flags(__f), _M_start_state(0), _M_subexpr_count(0),
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_M_has_backref(false)
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{ }
_NFA_base(_NFA_base&&) = default;
protected:
~_NFA_base() = default;
public:
_FlagT
_M_options() const
{ return _M_flags; }
_StateIdT
_M_start() const
{ return _M_start_state; }
_SizeT
_M_sub_count() const
{ return _M_subexpr_count; }
std::vector<size_t> _M_paren_stack;
_FlagT _M_flags;
_StateIdT _M_start_state;
_SizeT _M_subexpr_count;
bool _M_has_backref;
};
template<typename _TraitsT>
struct _NFA
: _NFA_base, std::vector<_State<_TraitsT>>
{
typedef _State<_TraitsT> _StateT;
typedef _Matcher<typename _TraitsT::char_type> _MatcherT;
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_NFA(const typename _TraitsT::locale_type& __loc, _FlagT __flags)
: _NFA_base(__flags)
{ _M_traits.imbue(__loc); }
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// for performance reasons _NFA objects should only be moved not copied
_NFA(const _NFA&) = delete;
_NFA(_NFA&&) = default;
_StateIdT
_M_insert_accept()
{
auto __ret = _M_insert_state(_StateT(_S_opcode_accept));
return __ret;
}
_StateIdT
_M_insert_alt(_StateIdT __next, _StateIdT __alt, bool __neg)
{
_StateT __tmp(_S_opcode_alternative);
// It labels every quantifier to make greedy comparison easier in BFS
// approach.
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__tmp._M_next = __next;
__tmp._M_alt = __alt;
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_repeat(_StateIdT __next, _StateIdT __alt, bool __neg)
{
_StateT __tmp(_S_opcode_repeat);
// It labels every quantifier to make greedy comparison easier in BFS
// approach.
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__tmp._M_next = __next;
__tmp._M_alt = __alt;
__tmp._M_neg = __neg;
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_matcher(_MatcherT __m)
{
_StateT __tmp(_S_opcode_match);
__tmp._M_matches = std::move(__m);
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_subexpr_begin()
{
auto __id = this->_M_subexpr_count++;
this->_M_paren_stack.push_back(__id);
_StateT __tmp(_S_opcode_subexpr_begin);
__tmp._M_subexpr = __id;
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_subexpr_end()
{
_StateT __tmp(_S_opcode_subexpr_end);
__tmp._M_subexpr = this->_M_paren_stack.back();
this->_M_paren_stack.pop_back();
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_backref(size_t __index);
_StateIdT
_M_insert_line_begin()
{ return _M_insert_state(_StateT(_S_opcode_line_begin_assertion)); }
_StateIdT
_M_insert_line_end()
{ return _M_insert_state(_StateT(_S_opcode_line_end_assertion)); }
_StateIdT
_M_insert_word_bound(bool __neg)
{
_StateT __tmp(_S_opcode_word_boundary);
__tmp._M_neg = __neg;
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_lookahead(_StateIdT __alt, bool __neg)
{
_StateT __tmp(_S_opcode_subexpr_lookahead);
__tmp._M_alt = __alt;
__tmp._M_neg = __neg;
return _M_insert_state(std::move(__tmp));
}
_StateIdT
_M_insert_dummy()
{ return _M_insert_state(_StateT(_S_opcode_dummy)); }
_StateIdT
_M_insert_state(_StateT __s)
{
this->push_back(std::move(__s));
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if (this->size() > _GLIBCXX_REGEX_STATE_LIMIT)
__throw_regex_error(regex_constants::error_space);
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return this->size()-1;
}
// Eliminate dummy node in this NFA to make it compact.
void
_M_eliminate_dummy();
#ifdef _GLIBCXX_DEBUG
std::ostream&
_M_dot(std::ostream& __ostr) const;
#endif
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public:
_TraitsT _M_traits;
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};
/// Describes a sequence of one or more %_State, its current start
/// and end(s). This structure contains fragments of an NFA during
/// construction.
template<typename _TraitsT>
class _StateSeq
{
public:
typedef _NFA<_TraitsT> _RegexT;
public:
_StateSeq(_RegexT& __nfa, _StateIdT __s)
: _M_nfa(__nfa), _M_start(__s), _M_end(__s)
{ }
_StateSeq(_RegexT& __nfa, _StateIdT __s, _StateIdT __end)
: _M_nfa(__nfa), _M_start(__s), _M_end(__end)
{ }
// Append a state on *this and change *this to the new sequence.
void
_M_append(_StateIdT __id)
{
_M_nfa[_M_end]._M_next = __id;
_M_end = __id;
}
// Append a sequence on *this and change *this to the new sequence.
void
_M_append(const _StateSeq& __s)
{
_M_nfa[_M_end]._M_next = __s._M_start;
_M_end = __s._M_end;
}
// Clones an entire sequence.
_StateSeq
_M_clone();
public:
_RegexT& _M_nfa;
_StateIdT _M_start;
_StateIdT _M_end;
};
//@} regex-detail
_GLIBCXX_END_NAMESPACE_VERSION
} // namespace __detail
} // namespace std
#include <bits/regex_automaton.tcc>