I would like to know if there is any way to obtain the address of the instantiation of a function template produced by a specific set of arguments.

#include <iostream>

template <typename T>
class A {}; 

template <typename T, typename T2>
int hello(A<T> a, A<T2> b, int c)
{
    return 69; 
}

int main()
{
    A<int> a;
    A<float> b;
    std::cout << (&hello)(a, b, 3) << "\n";                                                                                                                                                           

    return 0;
}

This code prints the value returned by the function call. How can I print the address of the version of "hello" instantiated for a and b parameters? I would like the types to be inferred by the compiler.

  • &hello<A<decltype(a)>> ? – Borgleader Apr 8 '15 at 18:44
  • @Borgleader: That's not quite right, the template parameter to hello would be the int, but there's no way to get int from a with the code as-is. – Mooing Duck Apr 8 '15 at 18:46
  • 2
    @Lalaland: parameters could be anything, not necessarily a class or class template. – Javier Cabezas Rodríguez Apr 8 '15 at 18:53
  • 1
    @FilipRoséen-refp: There are ways to get the return type, but to get the address, you need to know the parameters after implicit conversions, and there is no way to do this in C++. (If you find a counterexample, that would be groundbreaking, and I would be thrilled to see it) (Related, I'm thinking about the general case. In this case it might be possible because there's only one template function, with no overloads, or conversions) – Mooing Duck Apr 8 '15 at 18:59
  • 1
    @MooingDuck Not even C++17. We do get invocation type traits in the library fundamentals TS, but they only work on function objects, not generic overload sets. – T.C. Apr 8 '15 at 19:01

The process of determining the function to call based on the arguments is called overload resolution, and the standard lists in which cases it gets used:

13.3 Overload resolution [over.match]

2 Overload resolution selects the function to call in seven distinct contexts within the language:

(2.1) -- invocation of a function named in the function call syntax (13.3.1.1.1);

(2.2) -- invocation of a function call operator, a pointer-to-function conversion function, a reference-to-pointer-to-function conversion function, or a reference-to-function conversion function on a class object named in the function call syntax (13.3.1.1.2);

(2.3) -- invocation of the operator referenced in an expression (13.3.1.2);

(2.4) -- invocation of a constructor for direct-initialization (8.5) of a class object (13.3.1.3);

(2.5) -- invocation of a user-defined conversion for copy-initialization (8.5) of a class object (13.3.1.4);

(2.6) -- invocation of a conversion function for initialization of an object of a nonclass type from an expression of class type (13.3.1.5); and

(2.7) -- invocation of a conversion function for conversion to a glvalue or class prvalue to which a reference (8.5.3) will be directly bound (13.3.1.6).

Of these, the only one that applies to regular functions is 2.1, and that requires a f(args) context which only tells the caller the result.

So, what you ask for cannot be done. Not exactly, anyway.

Now, depending on what you want to accomplish, there are some things that are possible:

It is possible to get a pointer to the function if you know the exact signature: given template <typename T> int hello(A<T> a, A<T> b), you can obtain the address using that: static_cast<int(*)(A<int>,A<int>)>(hello). However, for this to work, you need to know the return type (which you might be able to obtain using decltype), and you need to know the parameter types (which may be different from the argument types, and which you aren't able to obtain reliably).

It is also possible to get a pointer to a function that, when called, will have the same effect as hello:

auto callable = +[](A<int> a, A<int> b) { return hello(a, b); };

The [](A<int> a, A<int> b) { return hello(a, b); } creates a lambda without any captures, and lambdas without any captures can implicitly be converted to a function pointer of a matching type. The + forces the use of that conversion, without requiring the type to be spelled out.

However, this will not have the same address as hello, so might not be suitable for subsequent comparisons.

That's the best you can get.

  • 1
    Might want to explain that +. It's a bit obscure. – T.C. Apr 8 '15 at 18:58
  • @T.C. Good point, added a note. – hvd Apr 8 '15 at 19:00
  • The pointer to lambda does not have the same effect as hello if copying A<int> has any side effects. If you move, then if the move ctor has side effects (or if hello treats rvalues differently) it won't have the same effect. If hello takes by-reference, any changes done to the objects won't be propagated out in the lambda solution. All of these basically require inspecting the implementation of the function template hello and its signature to the level that you might as well do it all manually, no? – Yakk - Adam Nevraumont Apr 8 '15 at 20:22
  • @Yakk You know how you want to call hello, so you can update the lambda to match, without having to know the implementation details of hello. If you know you'll want to pass lvalues, write auto callable = +[](A<int> &a, A<int> &b) { return hello(a, b); };. It'll work even if hello takes by value. Similarly rvalues, except for an added std::move: that too will work even if hello takes by value. But you do raise a valid point: there are some situations in which copies or moves of the parameters have a visible effect and in which that cannot be avoided. – hvd Apr 8 '15 at 20:32

I tried this in Ideone:

// A and hello defined as OP
int main()
{
    A<int> a;
    A<float> b;

    decltype(hello(a,b,3)) (*pf)(decltype(a), decltype(b), decltype(3))=hello;
    std::cout << (void*)pf << "\n";                                                                                                                                                           

    return 0;
}

It seemed to output a memory address.

  • I clarified the question with a comment from the asker on a deleted post: "I would like the types to be inferred by the compiler." – Mooing Duck Apr 8 '15 at 20:33
  • @MooingDuck Is the above edit any better? – quamrana Apr 9 '15 at 9:53
  • Yes. This works for the OP case where the parameter types are exact matches. – Mooing Duck Apr 9 '15 at 16:41

@hvd: AFAIK, you cannot declare a lambda without knowing the signature of the function you wanna wrap (lambdas cannot be templated). But you can use an intermediate class with a static method instead:

#include <functional>
#include <iostream>

template<class A>
void func(A a, int b)
{
    std::cout << "a=" << a << " b=" << b << "\n";
}

template<class... A>
class proxy_func
{
public:
    static auto call(A... args) -> decltype(func(args...))
        {
            return func(args...);
        }
};

template<template<class...> class P, class... User>
void* addr(User... user)
{
    return (void*)&P<User...>::call;
}

template<template<class...> class P, class... User>
auto call(User... user) -> decltype(P<User...>::call(user...))
{
    return P<User...>::call(user...);
}

template<class T>
void test()
{
    T value = 1;
    printf("func > %p\n", &func<T>);
    printf("func > ");
    func(value, 1);
    printf("proxy> %p\n", &proxy_func<T, int>::call);
    printf("proxy> ");
    proxy_func<T, int>::call(value, 1);
    printf("auto > %p\n", addr<proxy_func>(value, 1));
    printf("auto > ");
    call<proxy_func>(value, 1);
}

int main(int argc, char **argv)
{
    printf("==int==\n");
    test<int>();
    printf("==long==\n");
    test<long>();
}

The result is this:

g++ -std=c++11 -o /tmp/test /tmp/test.cpp && /tmp/test
==int==
func > 0x400a8d
func > a=1 b=1
proxy> 0x400ae6
proxy> a=1 b=1
auto > 0x400ae6
auto > a=1 b=1
==long==
func > 0x400b35
func > a=1 b=1
proxy> 0x400b91
proxy> a=1 b=1
auto > 0x400b91
auto > a=1 b=1

Of course, this requires declaring a generic proxy that knows about the name of the target function (nothing else), and that might not be acceptable as a solution for @JavierCabezasRodríguez.

PS: Sorry I did not post it as a comment, but I do not have enough reputation for it.

Edit

Using a proxy class instead of a lambda forgoes the need to know the number of parameters, so that you can use a hackishly macro approach to wrap any target function:

#define proxy(f)                                \
    template<class... A>                        \
    class proxy_ ## f                           \
    {                                           \
    public:                                                     \
        static auto call(A... args) -> decltype(f(args...))     \
        {                                                       \
            return f(args...);                                  \
        }                                                       \
    }

proxy(func);
  • Welcome to SO. It can take just a single good answer to gain enough reputation to comment, and I encourage you to do so if this is the level of comments you'd like to leave, this is useful. :) Lambdas can be templated in C++14 (look up auto parameters), but that wouldn't help, a templated lambda can be converted to multiple function pointer types, so the trick of using + to force the single possible conversion doesn't work. But... – hvd Apr 9 '15 at 17:20
  • ...you don't need templated lambdas, and you don't need the lambdas to match exactly to the function being called, you merely need to match the arguments you want to pass. The lambda body can take care of any implicit conversions from the argument types to the wrapped function's parameter types. For instance, void f(long l) { } int main() { auto x = +[](int a) { f(a); }; } is fine, and gives x type void(*)(int). It's okay that it doesn't exactly match the type of &f. – hvd Apr 9 '15 at 17:22
  • Right, I was thinking about avoiding the declaration of a lambda with a specific number of arguments. See edit on my response. – Lluís Vilanova Apr 9 '15 at 18:51

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