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This question is a follow-up of How to deduce the type of the functor's return value? I'm reformulating it in a more abstract way.

Given the pseudocode of a template function

template <typename Arg, typename Fn>
auto ComputeSomething(Arg arg, Fn fn) -> decltype(<decl-expr>)
{
// do something
// ............
return fn(<ret-expr>)
}

where <ret-expr> is an arbitrary expression which involves arg, what shall I use for <decl-expr> to set the return type of ComputeSomething equal to the return type of the functor.

The functor may be a class, a lambda or a function pointer.

Partial solutions I found so far.

(a) The answer for my linked question done by ecatmur. Essentially, it is repeating the return statement in <decl-expr>. Problems: it is error-prone and wouldn't work if contains local variables.

(b) It works only for function pointers

template <typename Arg, typename Ret>
Ret ComputeSomething(Arg arg, Ret(*fn)(Arg))

(c) It assumes that the argument of the functor is of type Arg (which may not hold in general) and requires Arg to be default-constructible

template <typename Arg, typename Fn>
auto ComputeSomething(Arg arg, Fn fn) -> decltype(fn(Arg())

(d) Using std::declval which is supposed to lift the default-constructible restriction, as suggested in how to deduce the return type of a function in template. Could anybody explain how it works?

template <typename Arg, typename Fn>
auto ComputeSomething(Arg arg, Fn fn) -> decltype(fn(std::declval<Arg>())
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I'm sorry to say this, but AFAIK this is not possible, because the trailing return does not see the function template being defined, while the body does. –  Johannes Schaub - litb Aug 21 '12 at 19:54

5 Answers 5

std::declval is a function template that is only declared (not defined). It can thus only be used in unevaluated contexts such as the argument to sizeof and decltype. It is declared to return an rvalue of the specified type. This allows you to use it to manufacture a dummy parameter for a function call in a decltype expression.

e.g.

typedef decltype(fn(std::declval<Arg>())) t;

declares t to be the type of the result of calling fn with an rvalue of type Arg. This is similar to your case (c) (fn(Arg())), but it doesn't require anything of Arg, so it works on types without default constructors.

If your return expression uses a local variable of type foo, then you can use decltype(fn(std::declval<foo>())), again regardless of how you construct a foo.

If you need an lvalue, such as a named object or an lvalue reference, then you can use std::declval<foo&>(). This allows you to handle the case where the type depends on whether you have an lvalue or an rvalue.

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2  
std::declval<Arg&>() is also something to be considered, especially considering you mention a local variable. –  Luc Danton Aug 20 '12 at 10:59

Use result_of. It is backwards compatible and takes all the ugly declval pain out of your code. You still need to remember to add rvalue reference qualifiers (&&) if you actually just forward values.

Something else I find important: Your function forwards arguments to another function. In such cases you should always use rvalue references to pass the arguments.

If all you are trying to do is improve maintainability: there are several attempts at a RETURNS macro around that try to minimize the repetition between the return type declaration and the actual return expression, but I haven't seen any that allows a function body that contains more than the actual return statement.

As for how declval works: Its compiler dependent. It isn't allowed to occur in an evaluated content and its argument can be an incomplete type. See 20.2.4

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I would advise against std::result_of. For once it isn't guaranteed to SFINAE, unlike decltype-based solutions. It also doesn't reflect the result type of a call -- it does more than that e.g. in relation with pointers to members. –  Luc Danton Aug 20 '12 at 11:01
    
@LucDanton I always perceived "doing more" as a benefit. Handling the case of pointers to member functions is horribly tedious and result_of solves that problem. Can you go more into detail about the SFINAE issue? –  pmr Aug 20 '12 at 11:11
    
There's no point in std::result_of computing a result type the function template can't deal with -- f(a, b, c) is a syntax error when f is a pointer to member. As for the SFINAE, consider an overloaded apply such that apply(f, args...) either results in f(args...) or, if it isn't well formed, resorts to f(*args...) (let's assume for the sake of simplicity that those two expressions are never simultaneously well-formed). You need SFINAE to remove either overload for a call to succeed. –  Luc Danton Aug 20 '12 at 11:26
    
@LucDanton Wouldn't you usually just dispatch on some kind of call_traits if you want to handle both raw member function pointer and normal functions or just require wrapping it in mem_fn. I'll probably have to work through the SFINAE part, because I don't get it. –  pmr Aug 20 '12 at 12:20
    
This isn't about function pointers (and std::mem_fn doesn't help with that anyway). And the point is that if you use decltype then it just works. –  Luc Danton Aug 20 '12 at 15:06
up vote 4 down vote accepted

Here's my own solution, the best I could get

template <typename Arg, typename Fn>
typename std::result_of<Fn(Arg)>::type ComputeSomething(Arg arg, Fn fn)
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To make (c) works for anything, you need 2 overloads. 1st as shown in (c), 2nd:

template <typename Arg, typename Ret>
Ret ComputeSomething(Arg arg, std::function<Ret(Arg)> fn)

Also, as gcc bug 54111 shows - deduction of return type is very unreliable.

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A variant of (b) working not only with function pointers should be something like

template<typename Arg, typename Ret>
Ret ComputeSomething (Arg arg, function<auto (Arg) -> Ret> f)
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