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This is more a best practice question than a language question in itself, since I already have a working solution to what seems to be a common stumbling block in C++.

I'm dealing with a typical cyclic dependency issue in template parameter substitutions. I have the following pair of classes:

template<class X>
class A { /* ... */ };

template<class X>
class B { /* ... */ };

and I want to instantiate each one as the following:

// Pseudocode -- not valid C++.
A<B> a;
B<A> b;

that is, I want to 'bind' A to B, and B to A.

I can solve the problem, in a gross way, through a forward declaration with inheritance trick:

class sA;
class sB;

class sA : public A<sB> { /* ... */ };
class sB : public B<sA> { /* ... */ };

but this brings in a set of problems, since sA and sB are not indeed A and B. For example, I cannot invoke A's constructors without properly duplicating them into sA, or somehow sparkling casts around the code.

My question is: what is the best practical way to deal with this issue? Any specially clever solution to this problem?

I am using both MSVC2008 and G++, but solutions with compiler-specific extensions are welcome.

Thanks,

Alek

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1  
Looks very weird to me. –  John Dibling Jan 26 '10 at 23:00
2  
I'd be interested in practical examples where that is needed, in my opinion the cyclic type dependencies shouldn't be there in the first place. –  Georg Fritzsche Jan 26 '10 at 23:00
    
gf, suppose class A is a server class, and class B is a client class, both conforming to a standard protocol, such that there may have a set of other client/server classes that may be connected together. For example, B queries data from A, and A sends events to B. Each of them has a pointer to the other (e.g., A contains a B* and B contains a A*), and they communicate by calling predefined methods on each other. This is how it is being used, and it has been working quite well despite this issue. I hope this renders the case clearer. Suggestions on the above design are also welcome. Thanks –  Alek Jan 26 '10 at 23:17
2  
You need to refactor. Factor out the common communication interface. –  GManNickG Jan 26 '10 at 23:28
1  
Seconded, you should break the type dependencies on at least one side. –  Georg Fritzsche Jan 26 '10 at 23:33

2 Answers 2

up vote 0 down vote accepted

Since a template's type names all its parameters, you can't have an endless loop of parameterization.

You are probably (certainly) just trying to send information in opposite directions at the same time. There's no problem with that, but you can't encapsulate the information in the classes that provide implementation.

template< class W > // define an abstract class to pass data
struct widget_traits {};

template<>
struct widget_traits< SpringySpring > { // specialize to put data in it
    struct properties { … };
    enum { boing = 3 };
};

template< class V >
struct veeblfetzer_traits {};

template<>
struct veeblfetzer_traits< VonNeumann > {
    typedef int potrzebie;
};

template< struct WT, struct VT > // pass info by using as argument
struct MyWidget { … };

template< struct VT, struct WT > // both ways
struct MyVeeblfetzer { … };
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As mentioned, the best practical way to deal with this is to refactor - break the dependencies by decoupling.

Possible options include:

  • interfaces by using virtual methods
  • static interfaces (possibly using type traits or concept checks)
  • using callbacks on one or both sides (possible eased via functors or signals)

This also helps you whenever your requirements suddenly change. Suppose you need a special server in some cases - it should of course support all the clients you've already written, you don't want to rewrite them. Or you need some special clients in some cases...
With your approach this would require rewriting both sides, whith a decoupled approach its just a matter of writing a modified version of the side you need to change.

Taking e.g. the static approach with clients:

template<class server>
class client {
    server& srv;
public:
    client(server& srv) : srv(srv) {};
    void work(const request& req) {
        srv.add_job(make_job(req));
    }
};

Here, client doesn't even need to know the concrete type of server - if it doesn't have a member function add_job(job&) or something compatible, compilation will simply fail.
If you want to get more formal, you could look into static assertions and concept checks.

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