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The fallowing code works with gcc 4.7. The idea is i have these generic functions, which work on sequences, pointers, tupples, pairs, user-defined types, and whatnot. If one of these functions is defined for a type, then all should be. The problem i'm having is determining how to specialize them. I decided to define a template class that would be specialized for each type, implementing each function, and then a free function that just forwards to the in-class implementation.

#include <utility>
#include <vector>
#include <iterator>
#include <memory>
#include <iostream>
#include <algorithm>

using namespace std;

template< class M > struct Mon;

template< class X, class F, 
          class M = Mon< typename decay<X>::type > > 
auto mon( X&& x, F f ) -> decltype( M::mon(declval<X>(),f) ) {
    return M::mon( forward<X>(x), f );

template< class C > struct IsSeqImpl {
    // Can only be supported on STL-like sequence types, not pointers.
    template< class _C > static true_type f(typename _C::iterator*);
    template< class _C > static false_type f(...);

    typedef decltype( f<C>(0) ) type;

template< class C > struct IsSeq : public IsSeqImpl<C>::type { };

/* Enable if is an STL-like sequence. */
template< class C, class R > struct ESeq : std::enable_if<IsSeq<C>::value,R> { };

template< class Seq > 
struct Mon : ESeq< Seq, Seq >::type
    template< class S, class F >
    static S mon( const S& s, F f ) {
        S r;
        transform( begin(s), end(s), back_inserter(r), f );
        return r;

template< class P > struct IsPtrImpl {
    template< class X > static true_type  f( X );
    template< class X > static false_type f( ... );

    typedef decltype( f(*declval<P>()) ) type;

template< class P > struct IsPtr : public IsPtrImpl<P>::type { };

template< class P, class R > struct EPtr : enable_if<IsPtr<P>::value,R> { };

template< class X > struct Mon< X* >
    template< class F, class R = decltype( declval<F>()(declval<X>()) ) >
    static unique_ptr<R> mon( X* x, F f ) {
        typedef unique_ptr<R> U;
        return x ? U( new R(f(*x)) ) : U(nullptr);

int add_one( int x ) { return x + 1; }

int main()
    vector<int> v = {1,2,3,4,5};    
    int x = 5;

    auto v2 = mon( v, add_one );
    auto x2 = mon( &x, add_one );

    // Should print 2 and 6.
    cout << v2[0] << '\n';
    cout << *x2 << '\n';

What i'd like to do is specialize Mon for more generic types but when i try to use the enable_if inheritance trick again, gcc complains Mon is already defined. I've also tried the technique of making the second template argument a true_ or false_type for SFINAE as mentioned in this question, but had no luck in getting it to compile.

Ideally, whenever i think of a category of types i want to define an action for, i should be able to write an enable_if and write the entire group of functions in a template specialization. This saves the trouble of writing one enable_if per function. Pessimistically, i'd have to specialize the group for every plausible type in each category in order to really be generic.

Can i possibly write this in a generic and extensible way?

PS: If only concepts were a part of C++11.

share|improve this question
What do you think using std::enable_if in the list of bases of a type achieves? (I ask because I want to make sure I understand what you want to achieve.) – Luc Danton Aug 25 '12 at 15:20
Do you mean ESeq in Mon<Seq>? Since all of Mon's functions are static the base object never gets constructed. It just prevents instantiation for non-sequence types. Though, it's entirely useless if i can't also for other types as well, which is why i wrote Mon<X*> instead of Mon<Ptr>. – SplinterOfChaos Aug 25 '12 at 15:36
up vote 3 down vote accepted

Caution: I am afraid I did not understood the question fully, so I may be out of line...

As far as I understand, you are trying to solve a compile-time dispatch issue, basically, the structure you would like is:

  • a generic function foo
  • a number of specializations that work for a given type (or a given family of type)

And the issue you have is both that:

  • you want as many foo_impl as you'd like, and adding new types should not impact the existing ones
  • you need to select the right foo_impl.

Does not it sound like simple function ?

This can be done, relatively simply, by using traits.

void foo_tag_detection(...) {} // void cannot be passed down as an argument
                               // so if this is picked up we are guaranteed
                               // a compile-time error

template <typename T>
void foo(T const& t) {
    foo_impl(t, foo_tag_detection(t));

Then we create a tag specific to our types, here for sequences

// For sequence we'll use a "sequence_tag", it can be reused for other functions
struct sequence_tag {};

And implement the sequence detection, as well as the overload of foo_impl we need

template <typename Seq>
auto foo_tag_detection(Seq const& s) -> decltype(s.begin(), s.end(), sequence_tag{}) {
    return sequence_tag{};

template <typename Seq>
void foo_impl(Seq const& s, sequence_tag) { ... }

Note that used decltype here to trigger SFINAE depending on the operations I needed s to support; it's a really powerful mechanism, and surprisingly terse.

share|improve this answer
This is very close to what i'm looking for! The only difference is that one type, like Monoid, might define several functions, in this case mappend and mzero. But i bet with just a little more work, i could specialize these types by tags, rather than the types themselves. So i might write Monoid<SeqTag> and Monoid<PtrTag>. BTW: I didn't know you could use the comma operator in a decltype! – SplinterOfChaos Aug 25 '12 at 15:44
@SplinterOfChaos: I must admit the comma operator is really handy in decltype :) – Matthieu M. Aug 25 '12 at 15:46
It works! Thanks very much. Surprising how simple things can be sometimes. – SplinterOfChaos Aug 25 '12 at 16:22
@SplinterOfChaos: the problem is, it's simple if you use the right combinations of things, but that recipe is not necessarily obvious; especially since in C++11 we are all just discovering how to use the new tools we've been given :) – Matthieu M. Aug 25 '12 at 16:27

Usually the tool for that job is template specialization with a little help from SFINAE. Here's a bit of untested code to give you a taste of what it looks like:

/* Reusable utilities */

template<typename... T>
struct dependent_false_type: std::false_type {};

enum class enabled;

template<typename Cond>
using EnableIf = typename std::enable_if<Cond::value, enabled>::type;

template<typename T>
using Bare = typename std::remove_cv<
    typename std::remove_reference<T>::type

/* Front-end */

// Second parameter is an implementation detail
template<typename T, typename Sfinae = enabled>
struct Mon {
    // It's not allowed to use the primary template
    static_assert( dependent_false_type<T>::value
                 , "No specialization of Mon found" );

    // In case a compiler forgets to honour the assertion
    template<typename... Ignored>
    static void mon(Ignored const&...) = delete;

// Front-end that delegates to the back-end
    typename T
    , typename F
    , typename B = Bare<T>
auto mon(T&& t, F&& f)
-> decltype( Mon<B>::template mon(std::declval<T>(), std::declval<F>()) )
{ return Mon<B>::template mon(std::forward<T>(t), std::forward<F>(f)); }

/* Back-end for pointers */

template<typename T>
struct Mon<T, EnableIf<std::is_pointer<T>>> {
    // Implement somewhere
        typename P
        , typename F
        , typename R = decltype( std::declval<F>()(*std::declval<P>()) )
    static std::unique_ptr<R> mon(P&& p, F&& f);

/* Back-end for ranges */

// Boost.Range does provide range concepts but not range traits
// so let's roll our own crude is_range

namespace detail {

// actual range concepts of Boost.Range also require some member types
// left as an exercise to the reader
template<typename T>
is_range_tester {
        typename T
        , typename = decltype( boost::begin(std::declval<T>()) )
        , typename = decltype( boost::end(std::declval<T>()) )
    static std::true_type test(int);

    static std::false_type test(long, ...);

} // detail

template<typename T>
struct is_range
    : decltype( detail::is_range_tester<T&>::template test<T>(0) )

template<typename T>
struct Mon<T, EnableIf<is_range<T>>> {
    /* implementation left as an exercise */

This is extensible, too. The biggest obstacle is that the conditions for each specialization must not overlap.

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