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c++ - How to parse mustache with Boost.Xpressive correctly?

I have tried to write a mustache parser with the excellent Boost.XPressive from the brilliant Eric Niebler. But since this is my first parser I am not familiar with the "normal" approach and lingo of compiler writers and feel a bit lost after a few days of trial&error. So I come here and hope someone can tell me the foolishness of my n00bish ways ;)

This is the HTML code with the mustache templates that I want to extract (http://mustache.github.io/): Now <bold>is the {{#time}}gugus {{zeit}} oder nicht{{/time}} <i>for all good men</i> to come to the {007} aid of their</bold> {{country}}. Result: {{#Res1}}Nullum <b>est</b> mundi{{/Res1}}

I have the following problems that I couldn't yet solve alone:

  • The parser I wrote doesn't print out anything but also doesn't issue a warning at compile-time. I managed before to have it print out parts of the mustache code but never all of it correctly.
  • I don't know how I can loop through all the code to find all occurrences but then also access them like with the smatch what; variable. The doc only shows how to find the first occurrence with "what" or how to output all the occurrences with the "iterator".
    • Actually I need a combination of both. Because once something is found I need to question the tags name and the content between the tags (which "what" would offer but the "iterator" won't allow) - and act accordingly. I guess I could use "actions" but how?
    • I think that it should be possible to do the tag finding and "content between tags" in one swoop, right? Or do I need to parser 2 times for that - and if so how?
  • Is it okay to parse the opening and closing brackets like I did, since there are always 2 brackets? Or should I do it in sequence or use repeat<2,2>('{')?
  • I still feel a bit unsure about the cases where keep() and by_ref() are necessary and when better not to use them.
  • I couldn't find the other options of the 4th parameter of the iterator sregex_token_iterator cur( str.begin(), str.end(), html, -1 ); here -1 which outputs all except the matching tags.
  • Is my parser string correctly finding nested mustache tags?
#include <boost/xpressive/xpressive_static.hpp>
#include <boost/xpressive/match_results.hpp>
typedef std::string::const_iterator It;
using namespace boost::xpressive;

std::string str = "Now <bold>is the {{#time}}gugus {{zeit}} oder nicht{{/time}} <i>for all good men</i> to come to the {007} aid of their</bold> {{country}}. Result: {{#Res1}}Nullum <b>est</b> mundi{{/Res1}}";
// Parser setup --------------------------------------------------------
mark_tag mtag (1), cond_mtag (2), user_str (3);
sregex brackets = "{{"
                  >> keep ( mtag = repeat<1, 20> (_w) )
                  >> "}}"
                  ;

sregex cond_brackets = "{{#"
                   >> keep (cond_mtag = repeat<1, 20> (_w) )
                   >> "}}"
                   >> * (
                       keep (user_str = + (*_s >> +alnum >> *_s) ) |
                       by_ref (brackets) |
                       by_ref (cond_brackets)
                   )
                   >> "{{/"
                   >> cond_mtag
                   >> "}}"
                   ;
sregex mexpression = *( by_ref (cond_brackets) | by_ref (brackets) );

// Looping + catching the results --------------------------------------
smatch what2;
std::cout << "
regex_search:
" << str << '
';
It strBegin = str.begin(), strEnd = str.end();
int ic = 0;

do
{
    if ( !regex_search ( strBegin, strEnd, what2, mexpression ) )
    {
        std::cout << ">> Breakout of this life...! Exit after " << ic << " loop(s)." << std::endl;
        break;
    }
    else
    {
        std::cout << "**Loop Nr: " << ic << '
';
        std::cout << "what2[0] "         << what2[0]      << '
'; // whole match
        std::cout << "what2[mtag] "      << what2[mtag]   << '
';
        std::cout << "what2[cond_mtag] " << what2[cond_mtag]   << '
';
        std::cout << "what2[user_str] "  << what2[user_str]    << '
';
        // display the nested results
        std::for_each (
            what2.nested_results().begin(),
            what2.nested_results().end(),
            output_nested_results() // <--identical function from E.Nieblers documentation
        );

        strBegin = what2[0].second;
    }
    ++ic;
}
while (ic < 6 || strBegin != str.end() );
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1 Answer

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Boost Spirit is built on Proto (by the same hero, Eric Niebler!), so I hope you don't mind if I uphold a personal tradition of mine and present an implementation in Boost Spirit.

I found it pretty tricky to see what you wanted to achieve, from just the code shown. Therefore I just went straight to the mustache docs and implemented a parser for the following AST:

namespace mustache {

    // any atom refers directly to source iterators for efficiency
    using boost::string_ref;
    template <typename Kind> struct atom {
        string_ref value;

        atom() { }
        atom(string_ref const& value) : value(value) { }
    };

    // the atoms
    using verbatim = atom<struct verbatim_tag>;
    using variable = atom<struct variable_tag>;
    using partial  = atom<struct partial_tag>;

    // the template elements (any atom or a section)
    struct section;

    using melement = boost::variant<
            verbatim,
            variable,
            partial, 
            boost::recursive_wrapper<section>
            // TODO comments and set-separators
        >;

    // the template: sequences of elements
    using sequence = std::vector<melement>;

    // section: recursively define to contain a template sequence
    struct section {
        bool       sense; // positive or negative
        string_ref control;
        sequence   content;
    };
}

As you can see, I've added support for negated sections as well as partial templates (i.e. variables that expand to a template to dynamically expand).

Here are the productions:

sequence     = *element;
element      = 
            !(lit("{{") >> '/') >> // section-end ends the current sequence
            (partial | section | variable | verbatim);

reference    = +(graph - "}}");

partial      = qi::lit("{{") >> "> " >> reference >> "}}";

sense        = ('#' > attr(true))
             | ('^' > attr(false));

section     %= "{{" >> sense >> reference [ section_id = phx::bind(&boost::string_ref::to_string, _1) ] >> "}}"
            >> sequence // contents
            > ("{{" >> ('/' >> lit(section_id)) >> "}}");

variable     = "{{" >> reference >> "}}";

verbatim     = +(char_ - "{{");

The only nifty thing is the use of a qi::local<> named section_id to check that the closing tag of a section matches the opening tag of the current section.

qi::rule<Iterator, mustache::sequence()> sequence;
qi::rule<Iterator, mustache::melement()> element;
qi::rule<Iterator, mustache::partial()>  partial;
qi::rule<Iterator, mustache::section(), qi::locals<std::string> >  section;
qi::rule<Iterator, bool()>                sense;                  // postive  or negative
qi::rule<Iterator, mustache::variable()> variable;
qi::rule<Iterator, mustache::verbatim()> verbatim;

I optimize things based on the assumption that the input data will stay around, so we don't need to copy actual data. This should avoid 99% of allocation needs here. I used boost::string_ref to achieve this here, and I think it's fair to say that this introduces the only bits of complexity (see full code below).

qi::rule<Iterator, boost::string_ref()>   reference;

Now we're ready to take our parser for a spin See It Live On Coliru

int main()
{
    std::cout << std::unitbuf;
    std::string input = "<ul>{{#time}}
<li>{{> partial}}</li>{{/time}}</ul>
 "
        "<i>for all good men</i> to come to the {007} aid of "
        "their</bold> {{country}}. Result: {{^Res2}}(absent){{/Res2}}{{#Res2}}{{Res2}}{{/Res2}}"
        ;
    // Parser setup --------------------------------------------------------
    typedef std::string::const_iterator It;
    static const mustache_grammar<It> p;

    It first = input.begin(), last = input.end();

    try {
        mustache::sequence parsed_template;
        if (qi::parse(first, last, p, parsed_template))
            std::cout << "Parse success
";
        else
            std::cout << "Parse failed
";

        if (first != last)
            std::cout << "Remaing unparsed input: '" << std::string(first, last) << "'
";

        std::cout << "Input:      " << input << "
";
        std::cout << "Dump:       ";
        Dumping::dumper()(std::cout, parsed_template) << "
";
    } catch(qi::expectation_failure<It> const& e)
    {
        std::cout << "Unexpected: '" << std::string(e.first, e.last) << "'
";
    }
}

Dumping::dumper simply prints the mustache template back from the parsed AST. You might wonder how dumper is implemented:

struct dumper : boost::static_visitor<std::ostream&>
{
    std::ostream& operator()(std::ostream& os, mustache::sequence const& v) const {
        for(auto& element : v)
            boost::apply_visitor(std::bind(dumper(), std::ref(os), std::placeholders::_1), element);
        return os;
    }
    std::ostream& operator()(std::ostream& os, mustache::verbatim const& v) const {
        return os << v.value;
    }
    std::ostream& operator()(std::ostream& os, mustache::variable const& v) const {
        return os << "{{" << v.value << "}}";
    }
    std::ostream& operator()(std::ostream& os, mustache::partial const& v) const {
        return os << "{{> " << v.value << "}}";
    }
    std::ostream& operator()(std::ostream& os, mustache::section const& v) const {
        os << "{{" << (v.sense?'#':'^') << v.control << "}}";
        (*this)(os, v.content);
        return os << "{{/" << v.control << "}}";
    }
};

Nothing overly complicated. Boost Variant really affords a declarative programming style. To illustrate this even more thoroughly, let's add expansion based on context objects!

I wasn't going to implement JSON just for this, so instead let's assume a context Value model like:

struct Nil { };

using Value = boost::make_recursive_variant<
    Nil,
    double,
    std::string,
    std::map<std::string, boost::recursive_variant_>,
    std::vector<boost::recursive_variant_>
>::type;

using Dict  = std::map<std::string, Value>;
using Array = std::vector<Value>;

Now we use binary visitation against mustache::melement and this context Value variant. This is a bit more code than just dumping, but let's look at the use-site first:

using namespace ContextExpander;
expander engine;

Value const ctx = Dict { 
    { "time", Array {
        Dict { { "partial", "gugus {{zeit}} (a.k.a. <u>{{title}}</u>)"},             { "title", "noon" },    { "zeit", "12:00" } },
        Dict { { "partial", "gugus {{zeit}} (a.k.a. <u>{{title}}</u>)"},             { "title", "evening" }, { "zeit", "19:30" } },
        Dict { { "partial", "gugus <u>{{title}}</u> (expected at around {{zeit}})"}, { "title", "dawn" },    { "zeit", "06:00" } },
    } },
    { "country", "ESP" },
    { "Res3", "unused" }
};

engine(std::cout, ctx, parsed_template);

This prints (See it Live On Coliru again):

Evaluation: <ul>
    <li>gugus 12:00 (a.k.a. <u>noon</u>)</li>
    <li>gugus 19:30 (a.k.a. <u>evening</u>)</li>
    <li>gugus <u>dawn</u> (expected at around 06:00)</li></ul>
 <i>for all good men</i> to come to the {007} aid of their</bold> ESP. Result: (absent)

Full Code Listing

for reference:

//#define BOOST_SPIRIT_DEBUG
#define BOOST_SPIRIT_USE_PHOENIX_V3
#include <boost/fusion/adapted/struct.hpp>
#include <boost/spirit/include/qi.hpp>
#include <boost/spirit/include/phoenix.hpp>
#include <boost/utility/string_ref.hpp>
#include <functional>
#include <map>

namespace mustache {

    // any atom refers directly to source iterators for efficiency
    using boost::string_ref;
    template <typename Kind> struct atom {
        string_ref value;

        atom() { }
        atom(string_ref const& value) : value(value) { }

        friend std::ostream& operator<<(std::ostream& os, atom const& v) { return os << typeid(v).name() << "[" << v.value << "]"; }
    };

    // the atoms
    using verbatim = atom<struct verbatim_tag>;
    using variable = atom<struct variable_tag>;
    using partial  = atom<struct partial_tag>;

    // the template elements (any atom or a section)
    struct section;

    using melement = boost::variant<
            verbatim,
            variable,
            partial, // TODO comments and set-separators
            boost::recursive_wrapper<section>
        >;

    // the template: sequences of elements
    using sequence = std::vector<melement>;

    // section: recursively define to contain a template sequence
    struct section {
        bool       sense; // positive or negative
        string_ref control;
        sequence   content;
    };
}

BOOST_FUSION_ADAPT_STRUCT(mustache::section, (bool, sense)(boost::string_ref, control)(mustache::sequence, content))

namespace qi = boost::spirit::qi;
namespace phx= boost::phoenix;

template <typename Iterator>
    struct mustache_grammar : qi::grammar<Iterator, mustache::sequence()>
{
    mustache_grammar() : mustache_grammar::base_type(sequence)
    {
        using namespace qi;
        static const _a_type section_id; // local
        using boost::phoenix::construct;
        using boost::phoenix::begin;
        using boost::phoenix::size;

        sequence     = *element;
        element      = 
                    !(lit("{{") >> '/') >> // section-end ends the current sequence
                    (partial | section | variable | verbatim);

        reference    = raw [ lexeme [ +(graph - "}}") ] ]
                        [ _val = construct<boost::string_ref>(&*begin(_1), size(_1)) ];

        partial      = qi::lit("{{") >> "> " >> reference >> "}}";

        sense        = ('#' > attr(true))
                    | ('^' > attr(false));

        section     %= "{{" >> sense >> reference [ section_id = phx::bind(&boost::string_ref::to_string, _1) ] >> "}}"
                    >> sequence // contents
                    > ("{{" >> ('/' >> lexeme [ lit(section_id) ]) >> "}}");

        variable     = "{{" >> reference >> "}}";

        verbatim     = raw [ lexeme [ +(char_ - "{{") ] ]
                        [ _val = construct<boost::string_ref>(&*begin(_1), size(_1)) ];

        BOOST_SPIRIT_DEBUG_NODES(
                (sequence)(element)(partial)(variable)(section

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