Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I have a list of types, from which I want to construct the list of all combinations with two elements. For example:

namespace mpl = boost::mpl;
typedef mpl::vector<int, long> typelist;
// mpl magic...
// the wanted list is equivalent to:
typedef mpl::vector<pair<int, int>, pair<int, long>,
                    pair<long, int>, pair<long, long> > combinations;

Here, pair<T1,T2> could be std::pair<T1,T2>, or mpl::vector<T1,T2>. How to do this? I would also be interested in removing the duplicates when we consider that pair<T1, T2> == pair<T2, T1>.
Thanks.

share|improve this question

3 Answers 3

up vote 6 down vote accepted

The list of combinations of a single type int with the list of types mpl::vector<int, long> can be computed by invoking mpl::fold:

typedef fold<
    mpl::vector<int, long>, vector<>, 
    push_back<mpl::_1, std::pair<int, mpl::_2> > 
>::type list_of_pairs;

Now, if we wrap that into a separate meta-function and invoke it for all types of the initial typelist we get:

typedef mpl::vector<int, long> typelist;

template <typename T, typename Result>
struct list_of_pairs
  : mpl::fold<typelist, Result, 
        mpl::push_back<mpl::_1, std::pair<T, mpl::_2> > > 
{};

typedef mpl::fold<
    typelist, mpl::vector<>, mpl::lambda<list_of_pairs<mpl::_2, mpl::_1> >
>::type result_type;

BOOST_MPL_ASSERT(
    mpl::equal<result_type, 
        mpl::vector4<
            std::pair<int, int>, std::pair<int,long>,
            std::pair<long,int>, std::pair<long,long> 
        > >::value);

EDIT: answering second question:

Making the result containing only unique elements (in the sense you mentioned) is a bit more involved. First you need to define a meta function comparing two elements and returning mpl::true_/mpl::false_:

template <typename P1, typename P2>
struct pairs_are_equal
  : mpl::or_<
        mpl::and_<
            is_same<typename P1::first_type, typename P2::first_type>,
            is_same<typename P1::second_type, typename P2::second_type> >,
        mpl::and_<
            is_same<typename P1::first_type, typename P2::second_type>, 
            is_same<typename P1::second_type, typename P2::first_type> > >
{};

Then we need to define a meta-function which tries to find a given element in a given list:

template <typename List, typename T>
struct list_doesnt_have_element
  : is_same<
        typename mpl::find_if<List, pairs_are_equal<mpl::_1, T> >::type, 
        typename mpl::end<List>::type>
{};

Now, this can be utilized to build a new list, making sure no duplicates are inserted:

typedef mpl::fold<
    result_type, mpl::vector<>,
    mpl::if_<
        mpl::lambda<list_doesnt_have_element<mpl::_1, mpl::_2> >, 
        mpl::push_back<mpl::_1, mpl::_2>, mpl::_1>

>::type unique_result_type;

All this is from the top of my head, so it may need some tweaking here or there. But the idea should be correct.


EDIT: minor corrections as outlined by @rafak

share|improve this answer
    
Thanks a lot! I didn't know how to use mpl::lambda. With the material about mpl you gave in your answer, I think I would be able now to answer my own question. –  rafak Jul 24 '10 at 9:26
    
Note: I can't edit your post, so here is the little changes I needed: in list_doesnt_have_element, replace end<List> by typename end<List>::type, idem for find_if. Also, I had to replace BOOST_STATIC_ASSERT(is_same< by BOOST_MPL_ASSERT((mpl::equal<, and another parenthesis at the end. I will remove this comment if someone can edit the answer. –  rafak Jul 24 '10 at 9:32

Excellent question. There are many interesting ways to solve this. Here is one.

All the unqualified names are in the mpl namespace, except for _1 and _2 which are in mpl::placeholders and boost::is_same, which is found in the type_traits library. The first template is a helper class to generate a list of all pairs consisting of a single element and each element of the given sequence. The second template aggregates all the results together to form the final sequence. Note that the results are not in a vector. You can do that easily with mpl::copy.

template <class Elem, class Seq>
struct single_combo {
    typedef typename transform<Seq
            ,lambda< std::pair<Elem, _1> >
        >::type type;
};

template <class Seq>
struct combo {
    typedef typename unique<Seq, is_same<_1,_2> >::type U;
    typedef typename fold<
        typename transform<U
            ,lambda< single_combo<_1, U> >
            >::type
        ,empty_sequence
        ,lambda< joint_view<_1,_2> >
    >::type type;
};

typedef typename combo<typelist>::type combinations;

Side note: If you're reading this and want a challenge, try answering this question yourself. It's a great plunge into MPL.

share|improve this answer
    
Excellent answer! thanks. I didn't know about the views. So I tried to replace the transform inside the fold by transform_view, and it seems to work as expected. But not if I change the transform in single_combo (although it works if used directly, not from combo). Do you have an explication? –  rafak Jul 24 '10 at 9:38

I've been doing some metaprogramming myself lately, have you looked into boost::mpl::set? That will eliminate duplicates. As for combinations, that sounds to me like mapping, what about boost::mpl::map? Beware that there are library limits that are imposed on the limits of types the sequences can take, though this can be adjusted with a macro, you're still at the mercy of your compiler's upper limit, depending on the number of types you need to handle.

share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.