/usr/include/lexertl/parser/parser.hpp

// parser.hpp
// Copyright (c) 2005-2011 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 LEXERTL_PARSER_HPP
#define LEXERTL_PARSER_HPP

#include <assert.h>
#include <algorithm>
#include "../bool.hpp"
#include "tree/end_node.hpp"
#include "tree/iteration_node.hpp"
#include "tree/leaf_node.hpp"
#include <map>
#include "../containers/ptr_stack.hpp"
#include "tokeniser/re_tokeniser.hpp"
#include "../runtime_error.hpp"
#include "tree/selection_node.hpp"
#include "tree/sequence_node.hpp"
#include "../size_t.hpp"
#include <vector>

namespace lexertl
{
namespace detail
{
/*
    General principles of regex parsing:
    - Every regex is a sequence of sub-regexes.
    - Regexes consist of operands and operators
    - All operators decompose to sequence, selection ('|') and iteration ('*')
    - Regex tokens are stored on a stack.
    - When a complete sequence of regex tokens is on the stack it is processed.

Grammar:

<REGEX>      -> <OREXP>
<OREXP>      -> <SEQUENCE> | <OREXP>'|'<SEQUENCE>
<SEQUENCE>   -> <SUB>
<SUB>        -> <EXPRESSION> | <SUB><EXPRESSION>
<EXPRESSION> -> <REPEAT>
<REPEAT>     -> charset | macro | '('<REGEX>')' | <REPEAT><DUPLICATE>
<DUPLICATE>  -> '?' | '??' | '*' | '*?' | '+' | '+?' | '{n[,[m]]}' |
                '{n[,[m]]}?'
*/

template<typename rules_char_type, typename sm_traits>
class basic_parser
{
public:
    enum {char_24_bit = sm_traits::char_24_bit};
    typedef typename sm_traits::char_type char_type;
    typedef typename sm_traits::id_type id_type;
    typedef basic_end_node<id_type> end_node;
    typedef typename sm_traits::input_char_type input_char_type;
    typedef basic_string_token<input_char_type> input_string_token;
    typedef basic_iteration_node<id_type> iteration_node;
    typedef basic_leaf_node<id_type> leaf_node;
    typedef basic_re_tokeniser<rules_char_type, input_char_type, id_type>
        tokeniser;
    typedef basic_node<id_type> node;
    typedef typename node::node_ptr_vector node_ptr_vector;
    typedef std::basic_string<rules_char_type> string;
    typedef basic_string_token<char_type> string_token;
    typedef std::map<string, const node *> macro_map;
    typedef basic_selection_node<id_type> selection_node;
    typedef basic_sequence_node<id_type> sequence_node;
    typedef std::map<string_token, std::size_t> charset_map;
    typedef std::pair<string_token, std::size_t> charset_pair;
    typedef bool_<sm_traits::compressed> compressed;

    basic_parser (const std::locale &locale_,
        node_ptr_vector &node_ptr_vector_, const macro_map &macro_map_,
        charset_map &charset_map_, const id_type eoi_) :
        _locale (locale_),
        _node_ptr_vector (node_ptr_vector_),
        _macro_map (macro_map_),
        _charset_map (charset_map_),
        _eoi (eoi_)
    {
    }

    node *parse (const rules_char_type *start_,
        const rules_char_type * const end_, const id_type id_,
        const id_type user_id_, const id_type next_dfa_,
        const id_type push_dfa_, const bool pop_dfa_,
        const std::size_t flags_, id_type &eol_id_, const bool seen_bol_,
        const bool macro_)
    {
        node *root_ = 0;
        state re_state_ (start_, end_, flags_, _locale, id_ == _eoi);
        token *lhs_token_ = 0;
        std::auto_ptr<token> rhs_token_ (new token);
        char action_ = 0;

        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = rhs_token_.release ();
        rhs_token_.reset (new token);
        tokeniser::next (re_state_, rhs_token_.get ());

        do
        {
            lhs_token_ = _token_stack->top ();
            action_ = lhs_token_->precedence (rhs_token_->_type);

            switch (action_)
            {
            case '<':
            case '=':
                _token_stack->push (static_cast<token *>(0));
                _token_stack->top () = rhs_token_.release ();
                rhs_token_.reset (new token);
                tokeniser::next (re_state_, rhs_token_.get ());
                break;
            case '>':
                reduce (re_state_);
                break;
            default:
                std::ostringstream ss_;

                ss_ << "A syntax error occurred: '" <<
                    lhs_token_->precedence_string () <<
                    "' against '" << rhs_token_->precedence_string () <<
                    "' at index " << re_state_.index () << ".";
                throw runtime_error (ss_.str ().c_str ());
                break;
            }
        } while (!_token_stack->empty ());

        if (_tree_node_stack.empty ())
        {
            throw runtime_error ("Empty rules are not allowed.");
        }

        assert (_tree_node_stack.size () == 1);

        node *lhs_node_ = _tree_node_stack.top ();

        _tree_node_stack.pop ();

        if (macro_)
        {
            // Macros have no end state...
            root_ = lhs_node_;
        }
        else
        {
            _node_ptr_vector->push_back (static_cast<end_node *>(0));

            node *rhs_node_ = new end_node (id_, user_id_, next_dfa_,
                push_dfa_, pop_dfa_);

            _node_ptr_vector->back () = rhs_node_;
            _node_ptr_vector->push_back (static_cast<sequence_node *>(0));
            _node_ptr_vector->back () = new sequence_node
                (lhs_node_, rhs_node_);
            root_ = _node_ptr_vector->back ();
        }

        if (seen_bol_)
        {
            fixup_bol (root_);
        }

        if (re_state_._eol_id != static_cast<id_type>(~0))
        {
            eol_id_ = re_state_._eol_id;
        }

        return root_;
    }

    static id_type bol_token ()
    {
        return static_cast<id_type>(~1);
    }

    static id_type eol_token ()
    {
        return static_cast<id_type>(~2);
    }

private:
    typedef typename input_string_token::range input_range;
    typedef typename tokeniser::state state;
    typedef basic_re_token<rules_char_type, input_char_type> token;
    typedef typename string_token::range range;
    typedef ptr_vector<string_token> string_token_vector;
    typedef ptr_stack<token> token_stack;
    typedef typename node::node_stack tree_node_stack;

    const std::locale &_locale;
    node_ptr_vector &_node_ptr_vector;
    const macro_map &_macro_map;
    charset_map &_charset_map;
    id_type _eoi;
    bool _compression;
    token_stack _token_stack;
    tree_node_stack _tree_node_stack;

    struct find_functor
    {
        // Pointer to stop warning about cannot create assignment operator.
        const string_token *_token;

        find_functor (const string_token &token_) :
            _token (&token_)
        {
        }

        bool operator () (const string_token *rhs_)
        {
            return *_token == *rhs_;
        }
    };

    void reduce (state &re_state_)
    {
        token *lhs_ = 0;
        token *rhs_ = 0;
        token_stack handle_;
        char action_ = 0;

        do
        {
            rhs_ = _token_stack->top ();
            handle_->push (static_cast<token *>(0));
            _token_stack->pop ();
            handle_->top () = rhs_;

            if (!_token_stack->empty ())
            {
                lhs_ = _token_stack->top ();
                action_ = lhs_->precedence (rhs_->_type);
            }
        } while (!_token_stack->empty () && action_ == '=');

        assert (_token_stack->empty () || action_ == '<');

        switch (rhs_->_type)
        {
        case BEGIN:
            // finished processing so exit
            break;
        case REGEX:
            // finished parsing, nothing to do
            break;
        case OREXP:
            orexp (handle_);
            break;
        case SEQUENCE:
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (OREXP);
            break;
        case SUB:
            sub (handle_);
            break;
        case EXPRESSION:
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (SUB);
            break;
        case REPEAT:
            repeat (handle_);
            break;
        case BOL:
            bol (handle_);
            break;
        case EOL:
            eol (handle_, re_state_);
            break;
        case CHARSET:
            charset (handle_, compressed ());
            break;
        case MACRO:
            macro (handle_);
            break;
        case OPENPAREN:
            openparen (handle_);
            break;
        case OPT:
        case AOPT:
            optional (rhs_->_type == OPT);
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (DUP);
            break;
        case ZEROORMORE:
        case AZEROORMORE:
            zero_or_more (rhs_->_type == ZEROORMORE);
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (DUP);
            break;
        case ONEORMORE:
        case AONEORMORE:
            one_or_more (rhs_->_type == ONEORMORE);
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (DUP);
            break;
        case REPEATN:
        case AREPEATN:
            repeatn (rhs_->_type == REPEATN, handle_->top ());
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (DUP);
            break;
        default:
            throw runtime_error
                ("Internal error regex_parser::reduce");
            break;
        }
    }

    void orexp (token_stack &handle_)
    {
        assert (handle_->top ()->_type == OREXP &&
            (handle_->size () == 1 || handle_->size () == 3));

        if (handle_->size () == 1)
        {
            std::auto_ptr<token> token_ (new token (REGEX));

            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = token_.release ();
        }
        else
        {
            token *token_ = handle_->top ();

            handle_->pop ();
            delete token_;
            token_ = 0;
            assert (handle_->top ()->_type == OR);
            token_ = handle_->top ();
            handle_->pop ();
            delete token_;
            token_ = 0;
            assert (handle_->top ()->_type == SEQUENCE);
            perform_or ();
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (OREXP);
        }
    }

    void perform_or ()
    {
        // perform or
        node *rhs_ = _tree_node_stack.top ();

        _tree_node_stack.pop ();

        node *lhs_ = _tree_node_stack.top ();

        _node_ptr_vector->push_back (static_cast<selection_node *>(0));
        _node_ptr_vector->back () = new selection_node (lhs_, rhs_);
        _tree_node_stack.top () = _node_ptr_vector->back ();
    }

    void sub (token_stack &handle_)
    {
        assert ((handle_->top ()->_type == SUB &&
            handle_->size () == 1) || handle_->size () == 2);

        if (handle_->size () == 1)
        {
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (SEQUENCE);
        }
        else
        {
            token *token_ = handle_->top ();

            handle_->pop ();
            delete token_;
            token_ = 0;
            assert (handle_->top ()->_type == EXPRESSION);
            // perform join
            sequence ();
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (SUB);
        }
    }

    void repeat (token_stack &handle_)
    {
        assert (handle_->top ()->_type == REPEAT &&
            handle_->size () >= 1 && handle_->size () <= 3);

        if (handle_->size () == 1)
        {
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (EXPRESSION);
        }
        else
        {
            token *token_ = handle_->top ();

            handle_->pop ();
            delete token_;
            token_ = 0;
            assert (handle_->top ()->_type == DUP);
            _token_stack->push (static_cast<token *>(0));
            _token_stack->top () = new token (REPEAT);
        }
    }

#ifndef NDEBUG
    void bol (token_stack &handle_)
#else
    void bol (token_stack &)
#endif
    {
        assert (handle_->top ()->_type == BOL &&
            handle_->size () == 1);

        // store charset
        _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
        _node_ptr_vector->back () = new leaf_node (bol_token (), true);
        _tree_node_stack.push (_node_ptr_vector->back ());
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REPEAT);
    }

#ifndef NDEBUG
    void eol (token_stack &handle_, state &re_state_)
#else
    void eol (token_stack &, state &re_state_)
#endif
    {
        // Done in two parts for VC6.
        const string_token eol_ ('\n');

        assert (handle_->top ()->_type == EOL &&
            handle_->size () == 1);
        re_state_._eol_id = lookup (eol_, compressed ());
        // store charset
        _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
        _node_ptr_vector->back () = new leaf_node (eol_token (), true);
        _tree_node_stack.push (_node_ptr_vector->back ());
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REPEAT);
    }

    // Uncompressed
    void charset (token_stack &handle_, const false_ &)
    {
        assert (handle_->top ()->_type == CHARSET &&
            handle_->size () == 1);

        const id_type id_ = lookup (handle_->top ()->_str, compressed ());

        // store charset
        _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
        _node_ptr_vector->back () = new leaf_node (id_, true);
        _tree_node_stack.push (_node_ptr_vector->back ());
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REPEAT);
    }

    // Compressed
    void charset (token_stack &handle_, const true_ &)
    {
        assert (handle_->top ()->_type == CHARSET &&
            handle_->size () == 1);

        std::auto_ptr<token> token_ (handle_->top ());

        handle_->pop ();
        create_sequence (token_);
    }

    // Slice wchar_t into sequence of char.
    void create_sequence (std::auto_ptr<token> &token_)
    {
        typename token::string_token::range_vector::iterator iter_ =
            token_->_str._ranges.begin ();
        typename token::string_token::range_vector::const_iterator end_ =
            token_->_str._ranges.end ();

        string_token_vector data_[char_24_bit ? 3 : 2];

        for (; iter_ != end_; ++iter_)
        {
            slice_range (*iter_, data_, bool_<char_24_bit> ());
        }

        push_ranges (data_, bool_<char_24_bit> ());

        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (OPENPAREN);
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REGEX);
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (CLOSEPAREN);
    }

    // 16 bit unicode
    void slice_range (const input_range &range_, string_token_vector data_[2],
        const false_ &)
    {
        const unsigned char first_msb_ = static_cast<unsigned char>
            ((range_.first >> 8) & 0xff);
        const unsigned char first_lsb_ = static_cast<unsigned char>
            (range_.first & 0xff);
        const unsigned char second_msb_ = static_cast<unsigned char>
            ((range_.second >> 8) & 0xff);
        const unsigned char second_lsb_ = static_cast<unsigned char>
            (range_.second & 0xff);

        if (first_msb_ == second_msb_)
        {
            insert_range (first_msb_, first_msb_, first_lsb_,
                second_lsb_, data_);
        }
        else
        {
            insert_range (first_msb_, first_msb_, first_lsb_, 0xff, data_);

            if (second_msb_ > first_msb_ + 1)
            {
                insert_range (first_msb_ + 1, second_msb_ - 1, 0, 0xff, data_);
            }

            insert_range (second_msb_, second_msb_, 0, second_lsb_, data_);
        }
    }

    // 24 bit unicode
    void slice_range (const input_range &range_, string_token_vector data_[3],
        const true_ &)
    {
        const unsigned char first_msb_ = static_cast<unsigned char>
            ((range_.first >> 16) & 0xff);
        const unsigned char first_mid_ = static_cast<unsigned char>
            ((range_.first >> 8) & 0xff);
        const unsigned char first_lsb_ = static_cast<unsigned char>
            (range_.first & 0xff);
        const unsigned char second_msb_ = static_cast<unsigned char>
            ((range_.second >> 16) & 0xff);
        const unsigned char second_mid_ = static_cast<unsigned char>
            ((range_.second >> 8) & 0xff);
        const unsigned char second_lsb_ = static_cast<unsigned char>
            (range_.second & 0xff);

        if (first_msb_ == second_msb_)
        {
            string_token_vector data2_[2];

            // Re-use 16 bit slice function
            slice_range (range_, data2_, false_ ());

            for (std::size_t i_ = 0, size_ = data2_[0]->size ();
                i_ < size_; ++i_)
            {
                insert_range (string_token (first_msb_, first_msb_),
                    *(*data2_[0])[i_], *(*data2_[1])[i_], data_);
            }
        }
        else
        {
            insert_range (first_msb_, first_msb_,
                first_mid_, first_mid_,
                first_lsb_, 0xff, data_);

            if (first_mid_ != 0xff)
            {
                insert_range (first_msb_, first_msb_,
                    first_mid_ + 1, 0xff,
                    0, 0xff, data_);
            }

            if (second_msb_ > first_msb_ + 1)
            {
                insert_range (first_mid_ + 1, second_mid_ - 1,
                    0, 0xff,
                    0, 0xff, data_);
            }

            if (second_mid_ != 0)
            {
                insert_range (second_msb_, second_msb_,
                    0, second_mid_ - 1,
                    0, 0xff, data_);
                insert_range (second_msb_, second_msb_,
                    second_mid_, second_mid_,
                    0, second_lsb_, data_);
            }
            else
            {
                insert_range (second_msb_, second_msb_,
                    0, second_mid_,
                    0, second_lsb_, data_);
            }
        }
    }

    // 16 bit unicode
    void insert_range (const unsigned char first_, const unsigned char second_,
        const unsigned char first2_, const unsigned char second2_,
        string_token_vector data_[2])
    {
        const string_token token_ (first_ > second_ ? second_ : first_,
            first_ > second_ ? first_ : second_);
        const string_token token2_ (first2_ > second2_ ? second2_ : first2_,
            first2_ > second2_ ? first2_ : second2_);

        insert_range (token_, token2_, data_);
    }

    void insert_range (const string_token &token_, const string_token &token2_,
        string_token_vector data_[2])
    {
        typename string_token_vector::vector::const_iterator iter_ =
            std::find_if (data_[0]->begin (), data_[0]->end (),
            find_functor (token_));

        if (iter_ == data_[0]->end ())
        {
            data_[0]->push_back (0);
            data_[0]->back () = new string_token (token_);
            data_[1]->push_back (0);
            data_[1]->back () = new string_token (token2_);
        }
        else
        {
            const std::size_t index_ = iter_ - data_[0]->begin ();

            (*data_[1])[index_]->insert (token2_);
        }
    }

    // 24 bit unicode
    void insert_range (const unsigned char first_, const unsigned char second_,
        const unsigned char first2_, const unsigned char second2_,
        const unsigned char first3_, const unsigned char second3_,
        string_token_vector data_[3])
    {
        const string_token token_ (first_ > second_ ? second_ : first_,
            first_ > second_ ? first_ : second_);
        const string_token token2_ (first2_ > second2_ ? second2_ : first2_,
            first2_ > second2_ ? first2_ : second2_);
        const string_token token3_ (first3_ > second3_ ? second3_ : first3_,
            first3_ > second3_ ? first3_ : second3_);

        insert_range (token_, token2_, token3_, data_);
    }

    void insert_range (const string_token &token_, const string_token &token2_,
        const string_token &token3_, string_token_vector data_[3])
    {
        typename string_token_vector::vector::const_iterator iter_ =
            data_[0]->begin ();
        typename string_token_vector::vector::const_iterator end_ =
            data_[0]->end ();
        bool finished_ = false;

        do
        {
            iter_ = std::find_if (iter_, end_, find_functor (token_));

            if (iter_ == end_)
            {
                data_[0]->push_back (0);
                data_[0]->back () = new string_token (token_);
                data_[1]->push_back (0);
                data_[1]->back () = new string_token (token2_);
                data_[2]->push_back (0);
                data_[2]->back () = new string_token (token3_);
                finished_ = true;
            }
            else
            {
                const std::size_t index_ = iter_ - data_[0]->begin ();

                if (*(*data_[1])[index_] == token2_)
                {
                    (*data_[2])[index_]->insert (token3_);
                    finished_ = true;
                }
                else
                {
                    ++iter_;
                }
            }
        } while (!finished_);
    }

    // 16 bit unicode
    void push_ranges (string_token_vector data_[2], const false_ &)
    {
        typename string_token_vector::vector::const_iterator viter_ =
            data_[0]->begin ();
        typename string_token_vector::vector::const_iterator vend_ =
            data_[0]->end ();
        typename string_token_vector::vector::const_iterator viter2_ =
            data_[1]->begin ();

        push_range (*viter_++);
        push_range (*viter2_++);
        sequence ();

        while (viter_ != vend_)
        {
            push_range (*viter_++);
            push_range (*viter2_++);
            sequence ();
            perform_or ();
        }
    }

    // 24 bit unicode
    void push_ranges (string_token_vector data_[3], const true_ &)
    {
        typename string_token_vector::vector::const_iterator viter_ =
            data_[0]->begin ();
        typename string_token_vector::vector::const_iterator vend_ =
            data_[0]->end ();
        typename string_token_vector::vector::const_iterator viter2_ =
            data_[1]->begin ();
        typename string_token_vector::vector::const_iterator viter3_ =
            data_[2]->begin ();

        push_range (*viter_++);
        push_range (*viter2_++);
        sequence ();
        push_range (*viter3_++);
        sequence ();

        while (viter_ != vend_)
        {
            push_range (*viter_++);
            push_range (*viter2_++);
            sequence ();
            push_range (*viter3_++);
            sequence ();
            perform_or ();
        }
    }

    void push_range (const string_token *token_)
    {
        const id_type id_ = lookup (*token_, compressed ());

        _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
        _node_ptr_vector->back () = new leaf_node (id_, true);
        _tree_node_stack.push (_node_ptr_vector->back ());
    }

    // Uncompressed
    id_type lookup (const input_string_token &charset_, const false_ &)
    {
        std::size_t id_ = sm_traits::npos ();
        typename charset_map::const_iterator iter_ =
            _charset_map.find (charset_);

        if (iter_ == _charset_map.end ())
        {
            id_ = _charset_map.size ();
            _charset_map.insert (charset_pair (charset_, id_));
        }
        else
        {
            id_ = iter_->second;
        }

        if (static_cast<id_type>(id_) < id_)
        {
            throw runtime_error ("IdType is not large enough "
                "to hold all ids.");
        }

        return static_cast<id_type>(id_);
    }

    // Compressed
    id_type lookup (const string_token &charset_, const true_ &)
    {
        // Converted to id_type below.
        std::size_t id_ = sm_traits::npos ();
        typename charset_map::const_iterator iter_;

        iter_ = _charset_map.find (charset_);

        if (iter_ == _charset_map.end ())
        {
            id_ = _charset_map.size ();
            _charset_map.insert (charset_pair (charset_, id_));
        }
        else
        {
            id_ = iter_->second;
        }

        if (static_cast<id_type>(id_) < id_)
        {
            throw runtime_error ("IdType is not large enough "
                "to hold all ids.");
        }

        return static_cast<id_type>(id_);
    }

    void macro (token_stack &handle_)
    {
        const token *top_ = handle_->top ();

        assert (top_->_type == MACRO && handle_->size () == 1);

        typename macro_map::const_iterator iter_ =
            _macro_map.find (top_->_extra);

        if (iter_ == _macro_map.end ())
        {
            const rules_char_type *name_ = top_->_extra.c_str ();
            std::basic_stringstream<input_char_type> ss_;
            std::ostringstream os_;

            os_ << "Unknown MACRO name '";

            while (*name_)
            {
                os_ << ss_.narrow (*name_++, ' ');
            }

            os_ << "'.";
            throw runtime_error (os_.str ());
        }

        _tree_node_stack.push (iter_->second->copy (_node_ptr_vector));
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REPEAT);
    }

    void openparen (token_stack &handle_)
    {
        token *token_ = handle_->top ();

        assert (token_->_type == OPENPAREN &&
            handle_->size () == 3);

        handle_->pop ();
        delete token_;
        token_ = handle_->top ();
        assert (token_->_type == REGEX);
        handle_->pop ();
        delete token_;
        token_ = 0;
        assert (handle_->top ()->_type == CLOSEPAREN);
        _token_stack->push (static_cast<token *>(0));
        _token_stack->top () = new token (REPEAT);
    }

    void sequence ()
    {
        node *rhs_ = _tree_node_stack.top ();

        _tree_node_stack.pop ();

        node *lhs_ = _tree_node_stack.top ();

        _node_ptr_vector->push_back (static_cast<sequence_node *>(0));
        _node_ptr_vector->back () = new sequence_node (lhs_, rhs_);
        _tree_node_stack.top () = _node_ptr_vector->back ();
    }

    void optional (const bool greedy_)
    {
        // perform ?
        node *lhs_ = _tree_node_stack.top ();
        // Don't know if lhs_ is a leaf_node, so get firstpos.
        typename node::node_vector &firstpos_ = lhs_->firstpos ();

        for (typename node::node_vector::iterator iter_ = firstpos_.begin (),
            end_ = firstpos_.end (); iter_ != end_; ++iter_)
        {
            // These are leaf_nodes!
            (*iter_)->greedy (greedy_);
        }

        _node_ptr_vector->push_back (static_cast<leaf_node *>(0));

        node *rhs_ = new leaf_node (node::null_token (), greedy_);

        _node_ptr_vector->back () = rhs_;
        _node_ptr_vector->push_back (static_cast<selection_node *>(0));
        _node_ptr_vector->back () = new selection_node (lhs_, rhs_);
        _tree_node_stack.top () = _node_ptr_vector->back ();
    }

    void zero_or_more (const bool greedy_)
    {
        // perform *
        node *ptr_ = _tree_node_stack.top ();

        _node_ptr_vector->push_back (static_cast<iteration_node *>(0));
        _node_ptr_vector->back () = new iteration_node (ptr_, greedy_);
        _tree_node_stack.top () = _node_ptr_vector->back ();
    }

    void one_or_more (const bool greedy_)
    {
        // perform +
        node *lhs_ = _tree_node_stack.top ();
        node *copy_ = lhs_->copy (_node_ptr_vector);

        _node_ptr_vector->push_back (static_cast<iteration_node *>(0));

        node *rhs_ = new iteration_node (copy_, greedy_);

        _node_ptr_vector->back () = rhs_;
        _node_ptr_vector->push_back (static_cast<sequence_node *>(0));
        _node_ptr_vector->back () = new sequence_node (lhs_, rhs_);
        _tree_node_stack.top () = _node_ptr_vector->back ();
    }

    // perform {n[,[m]]}
    // Semantic checks have already been performed.
    // {0,}  = *
    // {0,1} = ?
    // {1,}  = +
    // therefore we do not check for these cases.
    void repeatn (const bool greedy_, const token *token_)
    {
        const rules_char_type *str_ = token_->_extra.c_str ();
        std::size_t min_ = 0;
        bool comma_ = false;
        std::size_t max_ = 0;

        while (*str_>= '0' && *str_ <= '9')
        {
            min_ *= 10;
            min_ += *str_ - '0';
            ++str_;
        }

        comma_ = *str_ == ',';

        if (comma_) ++str_;

        while (*str_>= '0' && *str_ <= '9')
        {
            max_ *= 10;
            max_ += *str_ - '0';
            ++str_;
        }

        if (!(min_ == 1 && !comma_))
        {
            const std::size_t top_ = min_ > 0 ? min_ : max_;

            if (min_ == 0)
            {
                optional (greedy_);
            }

            node *prev_ = _tree_node_stack.top ()->
                copy (_node_ptr_vector);
            node *curr_ = 0;

            for (std::size_t i_ = 2; i_ < top_; ++i_)
            {
                node *temp_ = prev_->copy (_node_ptr_vector);

                curr_ = temp_;
                _tree_node_stack.push (static_cast<node *>(0));
                _tree_node_stack.top () = prev_;
                sequence ();
                prev_ = curr_;
            }

            if (comma_ && min_ > 0)
            {
                if (min_ > 1)
                {
                    node *temp_ = prev_->copy (_node_ptr_vector);

                    curr_ = temp_;
                    _tree_node_stack.push (static_cast<node *>(0));
                    _tree_node_stack.top () = prev_;
                    sequence ();
                    prev_ = curr_;
                }

                if (comma_ && max_)
                {
                    _tree_node_stack.push (static_cast<node *>(0));
                    _tree_node_stack.top () = prev_;
                    optional (greedy_);

                    node *temp_ = _tree_node_stack.top ();

                    _tree_node_stack.pop ();
                    prev_ = temp_;

                    const std::size_t count_ = max_ - min_;

                    for (std::size_t i_ = 1; i_ < count_; ++i_)
                    {
                        node *temp_ = prev_->copy (_node_ptr_vector);

                        curr_ = temp_;
                        _tree_node_stack.push (static_cast<node *>(0));
                        _tree_node_stack.top () = prev_;
                        sequence ();
                        prev_ = curr_;
                    }
                }
                else
                {
                    _tree_node_stack.push (static_cast<node *>(0));
                    _tree_node_stack.top () = prev_;
                    zero_or_more (greedy_);

                    node *temp_ = _tree_node_stack.top ();

                    prev_ = temp_;
                    _tree_node_stack.pop ();
                }
            }

            _tree_node_stack.push (static_cast<node *>(0));
            _tree_node_stack.top () = prev_;
            sequence ();
        }
    }

    void fixup_bol (node * &root_)const
    {
        typename node::node_vector *first_ = &root_->firstpos ();
        bool found_ = false;
        typename node::node_vector::const_iterator iter_ =
            first_->begin ();
        typename node::node_vector::const_iterator end_ =
            first_->end ();

        for (; iter_ != end_; ++iter_)
        {
            const node *node_ = *iter_;

            found_ = !node_->end_state () && node_->token () == bol_token ();

            if (found_) break;
        }

        if (!found_)
        {
            _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
            _node_ptr_vector->back () = new leaf_node (bol_token (), true);

            node *lhs_ = _node_ptr_vector->back ();

            _node_ptr_vector->push_back (static_cast<leaf_node *>(0));
            _node_ptr_vector->back () = new leaf_node
                (node::null_token (), true);

            node *rhs_ = _node_ptr_vector->back ();

            _node_ptr_vector->push_back (static_cast<selection_node *>(0));
            _node_ptr_vector->back () = new selection_node (lhs_, rhs_);
            lhs_ = _node_ptr_vector->back ();

            _node_ptr_vector->push_back (static_cast<sequence_node *>(0));
            _node_ptr_vector->back () = new sequence_node (lhs_, root_);
            root_ = _node_ptr_vector->back ();
        }
    }
};
}
}

#endif
libpuma-dev 1:1.1+svn20120529-2 / usr / include / lexertl / parser / parser.hpp
