I was recently surprised by the fact that lambdas can be assigned to std::functions with slightly different signatures. Slightly different meaning that return values of the lambda might be ignored when the function is specified to return void, or that the parameters might be references in the function but values in the lambda.

See this example (ideone) where I highlighted what I would suspect to be incompatible. I would think that the return value isn't a problem since you can always call a function and ignore the return value, but the conversion from a reference to a value looks strange to me:

int main() {
    function<void(const int& i)> f;
    //       ^^^^ ^^^^^    ^
    f = [](int i) -> int { cout<<i<<endl; return i; };
    //     ^^^    ^^^^^^
    return 0;

The minor question is: Why does this code compile and work? The major question is: What are the general rules for type conversion of lambda parameters and return values when used together with std::function?

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    Also: Is there a specific term for what I am describing here, or is type conversion correct?
    – anderas
    Jul 11 '16 at 8:35
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    Allowing a non-void function to be stored in std::function<void(blah)> is something GCC always supported, and is now required, see cplusplus.github.io/LWG/lwg-defects.html#2420 Jul 11 '16 at 9:43
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    "The major question is: What are the general rules for type conversion of lambda parameters and return values?" No, your question is about using lambdas with std::function, which is not the same as the general rules about lambda return types. Jul 11 '16 at 9:47
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    And in fact it's not specific to lambdas at all, since exactly the same rules apply for normal functions stored in std::function. Normal functions have parameters and return types too, and they can also undergo conversions when called via std::function. Jul 11 '16 at 9:55
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    And that's because std::function is not a function pointer, and is not a virtual override. It wraps a callable, adding a level of indirection, and conversions can take place in that level of indirection. See my answer for a direct analogy. Jul 11 '16 at 10:02

You can assign a lambda to a function object of type std::function<R(ArgTypes...)> when the lambda is Lvalue-Callable for that signature. In turn, Lvalue-Callable is defined in terms of the INVOKE operation, which here means that the lambda has to be callable when it is an lvalue and all its arguments are values of the required types and value categories (as if each argument was the result of calling a nullary function with that argument type as the return type in its signature).

That is, if you give your lambda an id so that we can refer to its type,

auto l = [](int i) -> int { cout<<i<<endl; return i; };

To assign it to a function<void(const int&)>, the expression

static_cast<void>(std::declval<decltype(l)&>()(std::declval<const int&>()))

must be well-formed.

The result of std::declval<const int&>() is an lvalue reference to const int, but there's no problem binding that to the int argument, since this is just the lvalue-to-rvalue conversion, which is considered an exact match for the purposes of overload resolution:

return l(static_cast<int const&>(int{}));

As you've observed, return values are discarded if the function object signature has return type void; otherwise, the return types have to be implicitly convertible. As Jonathan Wakely points out, C++11 had unsatisfactory behavior on this (Using `std::function<void(...)>` to call non-void function; Is it illegal to invoke a std::function<void(Args...)> under the standard?), but it's been fixed since, in LWG 2420; the resolution was applied as a post-publication fix to C++14. Most modern C++ compiler will provide the C++14 behavior (as amended) as an extension, even in C++11 mode.

  • @skypjack that's the special case for void return types, yes (since you can't implicity convert a value to void). But I think the OP is more concerned with the behavior of argument conversions and where those are OK.
    – ecatmur
    Jul 11 '16 at 9:02
  • It makes sense. I'd just put in evidence what's the specific case, that's all. ;-)
    – skypjack
    Jul 11 '16 at 9:05
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    @skypjack OK, I see your point. I've added the link to the last paragraph.
    – ecatmur
    Jul 11 '16 at 9:10
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    N.B. the question is marked C++11 and you're linking to a working draft of what will become C++17, quoting text that changed in 2015 (see LWG 2420). That's worth calling out, since eel.is/c++draft is not the standard. Jul 11 '16 at 9:53
  • declval<T>() can be an xvalue, an lvalue, or (in exactly four cases) a prvalue. There is no such thing as a "prvalue of type const int&"; declval<const int&>() is an lvalue of type const int.
    – T.C.
    Jul 11 '16 at 23:51

the conversion from a reference to a value looks strange to me


Does this look strange too?

int foo(int i) { return i; }

void bar(const int& ir) { foo(ir); }

This is exactly the same. A function taking an int by value gets called by another function, taking an int by const-reference.

Inside bar the variable ir gets copied, and the return value gets ignored. That's exactly what happens inside the std::function<void(const int&)> when it has a target with the signature int(int).


The assignment operator is defined to have the effect:


(14882:2011 par. 18)

The constructor that this references,

template <class F> function(F f);


F shall be CopyConstructible. f shall be Callable ( for argument type ArgTypes and return type R.

where Callable is defined as follows:

A callable object f of type F is Callable for argument types ArgTypes and return type R if the expression INVOKE(f, declval<ArgTypes>()..., R), considered as an unevaluated operand (Clause 5), is well formed (20.8.2).

INVOKE, in turn, is defined as:

  1. Define INVOKE(f, t1, t2, ..., tN) as follows:

    • ... cases for handling member functions omitted here ...
    • f(t1, t2, ..., tN) in all other cases.
  2. Define INVOKE(f, t1, t2, ..., tN, R) as static_cast<void>(INVOKE(f, t1, t2, ..., tN)) if R is cv void, otherwise INVOKE(f, t1, t2, ..., tN) implicitly converted to R.

Since the INVOKE definition becomes a plain function call, in this case, the arguments can be converted: If your std::function<void(const int&)> accepts a const int& then it can be converted to an int for the call. The example below compiles with clang++ -std=c++14 -stdlib=libc++ -Wall -Wconversion:

int main() {
    std::function<void(const int& i)> f;
    f = [](int i) -> void { std::cout << i << std::endl; };
    return 0;

The return type (void) is handled by the static_cast<void> special-case for the INVOKE definition.

Note, however, that at the time of writing the following generates an error when compiled with clang++ -std=c++1z -stdlib=libc++ -Wconversion -Wall, but not when compiled with clang++ -std=c++1z -stdlib=libstdc++ -Wconversion -Wall:

int main() {
    std::function<void(const int& i)> f;
    f = [](int i) -> int { std::cout << i << std::endl; return i;};
    return 0;

This is due to libc++ implementing the behaviour as specified in C++14, rather than the amended behaviour described above (thanks to @Jonathan Wakely for pointing this out). @Arunmu describes the libstdc++ type trait responsible for the same thing in his post. In this regard, implementations may behave slightly differently when handling callables with void return types, depending on whether they implement C++11, 14, or something newer.

  • Thank you for the answer! I really like the fact that you quoted the standard, but @ecatmur's answer explains the same things in a slightly more concise way without sacrificing any of the major points so I accepted that one. But IMHO your answer would also deserve the same amount of upvotes :-)
    – anderas
    Jul 11 '16 at 9:26
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    The libc++ behaviour is not a bug, it because libc++ implements the C++14 rule, not the one in the working draft you linked to. The rule changed with cplusplus.github.io/LWG/lwg-defects.html#2420 Jul 11 '16 at 9:50
  • @JonathanWakely Thanks for pointing this out. I've amended the answer to reflect that.
    – Andrew
    Jul 11 '16 at 10:49

Just adding to @ecatmur answer, g++/libstd++ just chose to ignore the return value of the callable, it's just as normal as one would do to ignore return value in regular code:

static void
_M_invoke(const _Any_data& __functor, _ArgTypes&&... __args)
   (*_Base::_M_get_pointer(__functor))(  // Gets the pointer to the callable

The type trait which explicitly permits this in libstd++ is :

template<typename _From, typename _To>     
using __check_func_return_type = __or_<is_void<_To>, is_convertible<_From, _To>>;

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