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Can you share any real-world examples of Boost::MPL usage (except lambdas), just to let me better understand its purposes and field of practical usage? The MPL documentation tutorial has a dimensional analysis example, but maybe because it's such an academic example it hasn't given me a feeling of Boost::MPL and when it can be effectively used.

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up vote 8 down vote accepted

I've used Boost.Mpl to generate variant-like classes.

For example, given a MPL type list such as this:

typedef boost::mpl::set<Foo, Bar, Baz> type_set;

I then use boost::mpl::fold to build a chain of classes derived from each others which each adds an std::unordered_set of one of the types in the type set. The end result is a class which contains an unordered_set<Foo>, an unordered_set<Bar> and an unordered_set<Baz>.

And because the class is specified in terms of a boost::mpl::set, I can iterate over these types to automatically generate other functions as well, such as an operator== which compares all of the unordered_sets.

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The fact is, Boost.MPL, like Boost.Preprocessor, are really building blocks.

Most of the times, you probably use it through other libraries, as a number of Boost libraries are built upon those two.

For example:

  • Boost.Fusion (which crosses the gaps between compile-time and run-time realms)
  • Boost.MultiIndex (for an easier interface)
  • Boost.Unit (for dimensional analysis)
  • Boost.Variant may, I think, also depends on it

You may use it unknowningly already :)

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I use a more enhanced dimensional analysis library called Boost.Units.

I've developed a compile-time reflection library and then used that library to build a generic class that provides runtime-reflection to any compile-time reflected type passed in. I've used that support to automatically generate UI components to edit the properties of such reflected types.

It's also paramount to the distribution of events within our application. For instance, when someone changes the units they wish the system to be in, I don't have to teach that system that new items have been added to given devices because the code uses MPL to analyze those types and just knows that something's been added and changes it.

I've just used metaprogramming techniques to wrap up the Qt signals into something that regains the type safety removed by their system and is able to connect with any functional entity.

But to tell the truth, you've almost certainly used practically applied metaprogramming techniques already when you've used standard algorithms like sort. A decent implementation of the sort algorithm uses a less evolved form of metaprogramming to analyze the iterators passed in and then uses tag-dispatching to initiate a sort algorithm capable of fully utilizing the features of those iterators.

Quite frankly, if you're not doing metaprogramming then you're not utilizing the power of C++ and you may as well be using something else.

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2  
I think the question is about Boost.MPL and not metaprogramming in general. – jalf Jan 9 '11 at 13:33
    
You can't talk about MPL without all the stuff that lead up to it. – Crazy Eddie Jan 9 '11 at 22:30
2  
but you can ask "do you use Boost.MPL" without asking "do you use any other example of template metaprogramming", in the same way that you can ask "do you drive a Volvo" without asking "Do you drive a car" – jalf Apr 26 '11 at 9:58

To add to Matthieu's answer, it's also used quite extensively throughout both Boost.Python and Luabind.

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boost.proto, boost.spirit (qi,karma,lex)... actually in most other boost libraries... – user2346536 Sep 10 '13 at 8:40

Something funny I did: https://github.com/edubois/static-factorial/blob/master/main.cpp

It uses a tiny part of boost::mpl to statically compute the value of factorial<8>()...

This can help to understand the main idea.

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I use boost::mpl (and boost::fusion) extensively in my stat_log library. This library allows the user to specify a hierarchy of statistic and logging tags and their associated behaviors, i.e. per-tag statistic types (histogram, counter, etc).

I rely heavily on metaprogramming to do the right thing with the user does:

stat_log::writeStat<IP_PKTS_RCVD>(450);

For example if the user defines the type trait:

template <>
struct stat_tag_to_type<IP_PKTS_RCVD>
{
   using type = Accumulator<
        stat_log::HistogramCount<
            int,
            1, //start bin
            1500, //stop bin
            10 //num_bits
        >
     >;
};

the "writeStat" call above will proxy (at compile time) to a histogram statistic. The powerful aspect of this design technique is the "writeStat" call site is not at all coupled with the particular statistic chosen.

I also use a wealth of MPL and boost::fusion to actually view the stats. Per your question, see the following files for the highest concentration of boost::mpl:

https://github.com/rjmccabe3701/stat_log/blob/master/include/stat_log/util/stat_log_impl.h https://github.com/rjmccabe3701/stat_log/blob/master/include/stat_log/util/tag_commander.h https://github.com/rjmccabe3701/stat_log/blob/master/include/stat_log/stat_log.h

especially the nifty template meta "function" in stat_log_impl.h:

//This template is used in conjunction with an MPL algorithm
// with the same semantics as mpl::find_if.
//BoolFunc is the "condition" metafunction.
//StatTagFunc is a metafunction that transforms the given
//   stat_tag into something the algorithm requires.
//   For example the "Identity" metafunction would work here.
//StatTagArgs is extra arguments to the BoolFunc
template <template<typename...> class BoolFunc,
          template<typename...> class StatTagFunc,
          class... StatTagArgs>
struct tag_node_query
{
   template<typename TheTagNode>
   struct apply
   {
      using stat_tag = typename TheTagNode::tag;
      using type = std::integral_constant
         <
            bool,
            BoolFunc<
               typename StatTagFunc<stat_tag>::type,
               StatTagArgs...
            >::value
         >;
   };
};
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