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Please don't get my "late binding" wrong, I don't mean usual late binding at runtime, I mean something else and cannot find a better word for it:

Consider I am working on a container (or similar) data structure Containor for some value type V that needs to compare these values with a comparator, so my first template looks like this

template<typename Val, typename Comp = std::less<Val>>
struct Containor{};

Now, my Containor structure makes use of another container internally. Which container is to be used should be configurable by template arguments as well, lets say the default is std::set. So my next version of Containor looks like this:

template<typename Val, typename Comp = std::less<Val>, typename Cont = std::set<Val,Comp>>
struct Containor{};

and here is where the code begins smelling IMHO. As long as the user is satisfied with the default implementation of the inner container, everything is fine. However, suppose he wants to use the new google btree set implementation btree::btree_set instead of std::set. Then he has to instanciate the template like this:

typedef Containor<int,std::less<int>,btree::btree_set<int,std::less<int>> MyContainor;
                                                     ^^^^^^^^^^^^^^^^^^^

I have underlined the part where my problem lies. The CLIENT CODE has to instanciate the btree_set with the right parameters. This honestly sucks, because the Containor class always needs a set of exactly the same type and comparator as its own first two template arguments. The client can - by accident - insert other types here! In addition, the client has the burden of choosing the right parameters. This might be easy in this case, but it hard if the inner container must for example be a set of pairs of the value type and some other type. Then the client has an even harder time getting the type parameters of the inner set correct.

So what I want is a way in which the client code only hands in the raw template and the Containor internally instanciates it with the correct arguments, i.e. something like that:

template<typename Val, typename Comp = std::less<Val>, typename Cont = std::set >
struct Containor{
    typedef Cont<Val,Comp> innerSet; 
//  ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ container instanciates the inner containor
};

typedef Containor<int,std::less<int>,btree::btree_set> MyContainor;
//                                   ^^^^^^^^^^^^^^^^
//                         client only hands in  raw template

Of course, this is no valid C++!

So I thought about ways to solve this problem. The only solution I could think of was writing "binder classes" for all data structures I want to use, like this:

struct btree_set_binder{

    template<typename V, typename C = std::less<V>>
    struct bind{
        typedef btree::btree_set<V,C> type;
    }
};

Now I can define my Containor with a set binder

template<typename Val, typename Comp = std::less<Val>, typename ContBinder = btree_set_binder >
struct Containor{
    typedef btree_set_binder::bind<Val,Comp>::type innerSet; 
//          ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^ works like a charm
};

Now, the user must only supply the desired binder class and the Containor will instanciate it with the right arguments. So these binder classes would be okay for me, but it is quite a hassle writing binder classes for all containers. So is there a better or easier way to bind template arguments "late" in C++11, i.e., inside another template that retrieves the raw template as parameter.

share|improve this question
    
Does your inner container always require a predicate? Then just extract that. –  Kerrek SB Feb 22 '13 at 17:13
3  
I guess what you need is template template parameters –  Andy Prowl Feb 22 '13 at 17:13
    
@Kerrek SB: I don't get what you mean. Can you elaborate on that a bit more. –  gexicide Feb 22 '13 at 17:13
1  
@gexicide: well, use Cont::key_compare for the comparator... Or if you want to be even more flexible, make a trait. In fact, I'll post that as an answer. –  Kerrek SB Feb 22 '13 at 17:14
2  
@gexicide: template templates exist, but you should generally avoid them for situations like yours, since you can never tell what a client template might actually look like. It's better for a template to expose its own parameters and use traits. –  Kerrek SB Feb 22 '13 at 17:20

3 Answers 3

up vote 3 down vote accepted

Maybe make your own comparator trait.

// Comparator trait primary template

template <typename T> stuct MyComparator
{
    typedef typename T::key_compare type;
};

// Comparator trait non-standard usage example

template <typename U, typename V, int N>
struct MyComparator<WeirdContainer<U, V, N>>
{
    typedef std::greater<V> type;
};

template <typename T, typename Cont = std::set<T>>
struct MyAdaptor
{
    typedef typename MyComparator<Cont>::type comparator_type;
    typedef T value_type;

    // ...
};

I've renamed your "Containor" to "MyAdaptor", since this sort of construction is usually called an "adaptor" class.

Usage:

MyAdaptor<int> a;    // uses std::set<int> and std::less<int>

MyAdaptor<double, WeirdContainer<bool, double, 27>> b;

Update: In light of the discussion, you could even remove the outer type argument entirely:

template <typename Cont> struct MyBetterAdaptor
{
    typedef MyAdaptorTraits<Cont>::value_type value_type;
    typedef MyAdaptorTraits<Cont>::pred_type pred_type;

    // ...
};

To be used like this:

MyBetterAdaptor<std::set<int>> c; // value type "int", predicate "std::less<int>"

Writing the MyAdaptorTraits template is left as an exercise.

share|improve this answer
    
still, how do you instanciate MyAdaptor with another Cont without specifying template arguments? –  gexicide Feb 22 '13 at 17:19
    
@Edit: But that doesn't solve my problem. Again, the user must supply all template arguments to WeirdContainer. when instanciating MyAdaptor<double, WeirdContainer<bool, double, 27>>. Exactly these arguments were what I wanted to get rid of. –  gexicide Feb 22 '13 at 17:21
    
@gexicide: You're going to have to repeat the value type, but that's an OK price to pay, since it's the most general design you can get. The standard library is constructed in the same way, and for a reason. –  Kerrek SB Feb 22 '13 at 17:21
    
@gexicide: Well, we do avoid having to specify the predicate repeatedly, right? That's a big improvement. I would consider this design perfectly acceptable. Again, compare with the standard library -- even they thought this was good library design. –  Kerrek SB Feb 22 '13 at 17:23
    
but see my post. What if the inner container may not of the value type but of a quite complex type like std::tuple<V,V,bool>. Do you want to shift the burden of getting this type correct to the user? –  gexicide Feb 22 '13 at 17:23

So what I want is a way in which the client code only hands in the raw template and the Containor internally instanciates it with the correct arguments,

So what you need is obviously a template template parameter:

// std::set has three template parameters, 
// we only want to expose two of them ...
template <typename V, typename C>
using set_with_defalloc = std::set<V,C>;

template<
    typename Val,
    typename Comp = std::less<Val>, 
    template <typename V, typename C> class Cont = set_with_defalloc>
struct Containor{
    typedef Cont<Val,Comp> innerSet; 
    // ...
};
share|improve this answer

You should be able to do it with template template parameters, as in:

template<typename Val, typename Comp = std::less<Val>, template <typename...> class ContBinder = std::set>
    struct Containor {
        typedef ContBinder<Val, Comp> innerSet;
        // ...
    };

Note: you need the variadic typename... because std::set takes three template parameters (the third being an allocator) while other containers might not.

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