I've recently found myself using the following macro with gcc 4.5 in C++11 mode:

#define RETURN(x) -> decltype(x) { return x; }

And writing functions like this:

template <class T>
auto f(T&& x) RETURN (( g(h(std::forward<T>(x))) ))

I've been doing this to avoid the inconvenience having to effectively write the function body twice, and having keep changes in the body and the return type in sync (which in my opinion is a disaster waiting to happen).

The problem is that this technique only works on one line functions. So when I have something like this (convoluted example):

template <class T>
auto f(T&& x) -> ...
   auto y1 = f(x);
   auto y2 = h(y1, g1(x));
   auto y3 = h(y1, g2(x));
   if (y1) { ++y3; }
   return h2(y2, y3);

Then I have to put something horrible in the return type.

Furthermore, whenever I update the function, I'll need to change the return type, and if I don't change it correctly, I'll get a compile error if I'm lucky, or a runtime bug in the worse case. Having to copy and paste changes to two locations and keep them in sync I feel is not good practice.

And I can't think of a situation where I'd want an implicit cast on return instead of an explicit cast.

Surely there is a way to ask the compiler to deduce this information. What is the point of the compiler keeping it a secret? I thought C++11 was designed so such duplication would not be required.

  • 6
    Maybe you need to reconsider the code you're writing if you have so many functions using decltype. We survived a long time without decltype at all...
    – SoapBox
    Dec 24, 2010 at 1:54
  • 5
    (You make it sound like you're changing the function every other hour.) Yes, it would be nice if the compiler could deduce the return type automatically, but it simply isn't there, and there's a point where you have to stop trying to be the compiler and just write code it accepts. (And yes, C++0x alleviates many things, but it can't, unfortunately, go all out.) So just specify the return type.
    – GManNickG
    Dec 24, 2010 at 1:55
  • 21
    I don't think all the negative comments are reasonable. Boost libraries are full of function objects with things like ::return_type to work around these sort of issues. Do you really think that having to define a new class just to define the return type of your function is 'readable'?! I don't see what is so unreadable about not having to replicate the same information in three different ways.
    – Clinton
    Dec 24, 2010 at 13:48
  • 6
    @ybungalobill: Can you easily reason about the return type of boost fusion vectors? If not, do you think their design is wrong? And if so, how would you do it?
    – Clinton
    Dec 25, 2010 at 23:42
  • 4
    There's a reason that decltype and the lazy return type syntax was introduced, and that's because it's impossible or unbelievably hard to determine the type of many functions involving forwarding beforehand. @SoapBox: I disagree wholeheartedly in a respectful manner.
    – Puppy
    Dec 26, 2010 at 14:11

6 Answers 6


It would appear that g++ 4.8 is getting an implementation of auto return type deduction. The patch was put in by Jason Merrill who is also sending a paper for C++-1Y for the feature. The feature is available with -std=c++1y.

Still playing with it.

  • 7
    Return type deduction has been voted into C++14. The latest paper has the details.
    – emsr
    Apr 28, 2013 at 2:23

The rationale for this behavior is given in the draft, 8.3.5p12:

A trailing-return-type is most useful for a type that would be more complicated to specify before the declarator-id:

template <class T, class U> auto add(T t, U u) -> decltype(t + u);

rather than

template <class T, class U> decltype((*(T*)0) + (*(U*)0)) add(T t, U u);

So this is really only meant to simplify the case where referring to the parameter names helps.

If you assume that C++ could always infer the return type of functions from the function body: this is not going to fly. It's a goal of C++ (and C) to allow modularity by separating declaration from implementation, so at the point of the call, you may not have the body of the function available. However, every caller needs to know the parameter types and the return type of every function/method being called.


If you are simply trying to set the return type, make it a template argument. This way you can change everything related to the return type without actually changing the function. You can put a default return type if you want like in this example.

template <class R = int, class T>
R f(T&& x)
   return h2(y2, y3);

The code below demonstrates it's effectiveness.


#include <iostream>
#include <iomanip>

template <class T, class S>
T h2(T& x, S& y)
  return x + y;

template <class R = int, class T>
R f(T& x)
  auto y2 = x;
  auto y3 = x;
  return h2(y2, y3);

int main(int argc, char** argv)
  int x = 7;
  std::string str = "test! ";

  auto d = f<double>(x);
  auto i = f(x); // use default type (int)
  auto s = f<std::string>(str);

  std::cout << std::fixed << std::setprecision(4);
  std::cout << "double: " << d << std::endl;
  std::cout << "int: " << i << std::endl;
  std::cout << "string: " << s << std::endl;

  return 0;


double: 14.0000
int: 14
string: test! test!

Unfortunately, the exact functionality you are looking for does not exist (yet) and is not part of the C++0x spec. However, it is possible this may be part of the C++1x spec when it is drafted. until then, stick to templates.


EDIT: oops, I just realized that there's a scoping difference between the trailing-return-type specifier and the return statement. Specifically:

auto f(int a)
    char r[sizeof(f(a))+1];
    return r;


Previous answer:

It's unfortunate that the language does not provide a syntax to have the compiler infer the return type in this case, because it's trivial to show that inference is possible.

Specifically, we are talking about the case where there is exactly one return statement inside the function.

Independent of where in the function that return statement is, or how complex the preceding code is, it should be clear that the following transformation is possible:

return (ugly expression);


auto return_value = (ugly expression);
return return_value;

If the compiler can infer the type of return_value (and according to the C++0x rules, it can), then the inferred type of return_value can be chosen as the return type of the function.

It therefore seems to me that a modification to C++0x where the trailing return type specifier should only be required when the multiplicity of return statements is not exactly one would be feasible and solve the problem.

  • But you can write auto f = [&](int a) { char r[sizeof(f(a))+1]; return r; };, and compilers just give you an error if you do, e.g., “error: variable 'f' declared with 'auto' type cannot appear in its own initializer”
    – Charphacy
    Apr 2, 2013 at 17:10

I agree with Yttrill. Return type deduction has already been proved to be a feasible practice in languages like Haskell, and since C++ has already achieved 'auto', it is just one step further to achieve return type deduction. This deduction should happens at the time of specialization, not template definition, since information of the real type supplied to the template is needed. The separate of declaration and definition is no longer a common practice in generic C++, because template body must be written in header files, and hence template bodies almost always go with template declarations. In situations where there are multiple return statements and types of them do not match, the compiler can happily report en error. In summary, return type deduction is totally possible in C++, if the committee wants to. And it's VERY important, because the duplication of manually writing return types hinders the pervasive use of small generic helper functions, which is such a common practice in functional and generic programming.

  • 1
    Template bodies do not really have to be written in header files: you can write the body in .cpp .cxx as usual and have it explicitly instantiated for instances that you can use. This does not work for all use-cases, but it often does help reduce compilation time and improve readability.
    – EFraim
    Dec 18, 2013 at 9:41

Many programming languages including Ocaml and Felix can deduce the return type of a function and do not require it to be specified. In Ocaml you can and must specify it in an interface. In Felix I have found for some functions it is wise to specify it in library code to make it easier to use.

I am surprised "auto" doesn't work for return types, it was certainly on the plate. Was this considered too hard to implement? [It isn't trivial given that a function can be recursive].

Ohhh .. now I see. The problem is the stupid template design feature "dependent names":

template<class T> auto f(T a) { return a.f(); }

So whilst it is a bit tricky to compute the return type of an ordinary function due to overloading, it is impossible with templates due to dependent name lookup: it could only be done after instantiation. But overloading must happen before that. So auto return types can't go in the language because it doesn't generalise to templates.

  • 1
    Yttrill: Could you elaborate on this? Would "template class<T> decltype(a.f()) f(T a) { return a.f(); } fail? (which is what my macro does)
    – Clinton
    Jan 1, 2011 at 5:31
  • what you are missing that "auto" for return types means that you need to use the trailing-return-type declaration (-> T). Jan 1, 2011 at 15:37
  • If you have multiple return statements with different types, you need to find a superset of all types specified. I think this feature will be needlessly complicated and result in a lot of cryptic errors and corner cases: (e.g. you return pointers A* and B* to forward declared classes, which are actually derive from on another, if only forward declarations are available, deduction will fail).
    – Alex B
    May 12, 2011 at 12:02
  • In C++14, this is possible. Apr 13, 2015 at 18:12

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