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I'm trying to check whether a functor is compatible with a given set of parametertypes and a given return type (that is, the given parametertypes can be implicitely converted to the actual parametertypes and the other way around for the return type). Currently I use the following code for this:

    template<typename T, typename R, template<typename U, typename V> class Comparer>
    struct check_type
    { enum {value = Comparer<T, R>::value}; };

    template<typename T, typename Return, typename... Args>
    struct is_functor_compatible
    {
        struct base: public T
        {
            using T::operator();
            std::false_type operator()(...)const;
        };
        enum {value = check_type<decltype(std::declval<base>()(std::declval<Args>()...)), Return, std::is_convertible>::value};
    };

check_type<T, V, Comparer> This works quite nicely in the majority of cases, however it fails to compile when I'm testing parameterless functors like struct foo{ int operator()() const;};, beccause in that case the two operator() of base are apperently ambigous, leading to something like this:

error: call of '(is_functor_compatible<foo, void>::base) ()' is ambiguous
note: candidates are:
note: std::false_type is_functor_compatible<T, Return, Args>::base::operator()(...) const [with T = foo, Return = void, Args = {}, std::false_type = std::integral_constant<bool, false>]
note: int foo::operator()() const

So obvoiusly I need a different way to check this for parameterless functors. I tried making a partial specialization of is_functor_compatible for an empty parameterpack, where I check if the type of &T::operator() is a parameterless memberfunction, which works more or less. However this approach obviously fails when the tested functor has several operator().

Therefore my question is if there is a better way to test for the existence of a parameterless operator() and how to do it.

share|improve this question
up vote 8 down vote accepted

When I want to test if a given expression is valid for a type, I use a structure similar to this one:

template <typename T>
struct is_callable_without_parameters {
private:
    template <typename T1>
    static decltype(std::declval<T1>()(), void(), 0) test(int);
    template <typename>
    static void test(...);
public:
    enum { value = !std::is_void<decltype(test<T>(0))>::value };
};
share|improve this answer
    
seems to work so far , but since I'd like to understand the code, could you explain what exactly this decltype(std::declval<T1>()(), void(), 0) is doing? – Grizzly Oct 26 '11 at 17:16
3  
@Grizzly The first part is for SFINAE on the expression we're looking for. The 0 at the end is to have an int return type, because in case the std::declval<T1>()() part has void as return type, you wouldn't be able to distinguish the overloads. And the void() in the middle is to prevent nasty things because of overloaded comma operators. – R. Martinho Fernandes Oct 26 '11 at 17:51
    
that works for the non parameterless case too (using std::declval<T1>()(std::declval<Args>()...)), so I don't even have to specialize for parameterless constructors, so thanks a lot – Grizzly Oct 26 '11 at 18:15
    
@Grizzly yes this is easily adaptable to any expression you want :) – R. Martinho Fernandes Oct 26 '11 at 18:18

Have you tried something like:

template<size_t>
class Discrim
{
};

template<typename T>
std::true_type hasFunctionCallOper( T*, Discrim<sizeof(T()())>* );

template<typename T>
std::false_type hasFunctionCallOper( T*, ... );

After, you discriminate on the return type of hasFunctionCallOper((T*)0, 0).

EDITED (thanks to the suggestion of R. Martinho Fernandes):

Here's the code that works:

template<size_t n>
class CallOpDiscrim {};

template<typename T>
TrueType hasCallOp( T*, CallOpDiscrim< sizeof( (*((T const*)0))(), 1 ) > const* );
template<typename T>
FalseType hasCallOp( T* ... );

template<typename T, bool hasCallOp>
class TestImpl;

template<typename T>
class TestImpl<T, false>
{
public:
    void doTellIt() { std::cout << typeid(T).name() << " does not have operator()" << std::endl; }
};

template<typename T>
class TestImpl<T, true>
{
public:
    void doTellIt() { std::cout << typeid(T).name() << " has operator()" << std::endl; }
};

template<typename T>
class Test : private TestImpl<T, sizeof(hasCallOp<T>(0, 0)) == sizeof(TrueType)>
{
public:
    void tellIt() { this->doTellIt(); }
};
share|improve this answer
    
This doesn't seem to work, the compiler doesn't like T()() (not suprising so I tried using std::declval<T>()() instead, but hasFunctionCallOper((T*)0, 0) never seems to match the first function, even if the operator() exists – Grizzly Oct 26 '11 at 17:42
    
@Grizzly I'll admit that I didn't test it; I have used something similar for named functions. (But perhaps the expression in the sizeof was more along the lines of (*((T*)0))() Otherwise, it will fail if there is no default constructor as well.) Exceptionally, my response here was only a suggestion of something you might try; I didn't have time to experiment myself, in order to give a definitive answer. – James Kanze Oct 27 '11 at 7:57
    
@Grizzly OK. I've tested it. It works for all return values except void; sizeof of a void doesn't work. So I'll defer to R. Martinho Fernandes: using sizeof( (*((T const*)0))(), 1 ) works (or drop the const if you want only non-const operator()). I'll edit my posting to add the code that works (but the credit really goes to Martinho, for the idea of using the comma operator followed by an integer). – James Kanze Oct 27 '11 at 8:48

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