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I have an std::function object I'm using as a callback to some event. I'm assigning a lambda to this object, within which, I assign the object to a different lambda mid execution. I get a segfault when I do this. Is this not something I'm allowed to do? If so, why? And how would I go about achieving this?


std::function<void(Data *)> doCallback;


// This gets called after a sendDataRequest call returns with data
void onIncomingData(Data *data)
    if ( doCallback )


doCallback =
    [=](Data *data)
        // Change the callback within itself because we want to do 
        // something else after getting one request  
        doCallback =
            [=](Data *data2)
                ... do some work ...
share|improve this question
Can you reproduce the issue with a small, compilable testcase (e.g. without the data communication)? This would go a long way towards helping you (by giving everyone a chance to debug through the program etc.). – Luc Danton Apr 29 '14 at 6:40
What LucDanton says. Can you provide an SSCCE? – Angew Apr 29 '14 at 6:41
I assume sendDataRequest(); introduces an infinite recursion. – Dieter Lücking Apr 29 '14 at 6:51

The standard does not specify when in the operation of std::function::operator() that the function uses its internal state object. In practice, some implementations use it after the call.

So what you did was undefined behaviour, and in particular it crashes.

struct bob {
  std::function<void()> task;
  std::function<void()> next_task;
  void operator()(){

now if you want to change what happens when you next invoke bob within bob(), simply set next_task.

share|improve this answer

Short answer

It depends on whether, after the (re)assignment, the lambda being called accesses any of its non static data members or not. If it does then you get undefined behavior. Otherwise, I believe nothing bad should happen.

Long answer

In the OP's example, a lambda object -- denoted here by l_1 -- held by a std::function object is invoked and, during its execution, the std::function object is assigned to another lambda -- denoted here by l_2.

The assignment calls template<class F> function& operator=(F&& f); which, by, has the effects of


where f binds to l_2 and *this is the std::function object being assigned to. At this time, the temporary std::function holds l_2 and *this holds l_1. After the swap the temporary holds l_1 and *this holds l_2 (*). Then the temporary is destroyed and so is l_1.

In summary, while running operator() on l_1 this object gets destroyed. Then according to 12.7/1

For an object with a non-trivial constructor, referring to any non-static member or base class of the object before the constructor begins execution results in undefined behavior. For an object with a non-trivial destructor, referring to any non-static member or base class of the object after the destructor finishes execution results in undefined behavior.

Lambdas non static data members correspond its captures. So if you don't access them, then it should be fine.

There's one more important point raised by Yakk's answer. As far as I understand, the concern was whether std::function::operator(), after having forwarded the call to l_1, tries to access l_1 (which is now dead) or not? I don't think this is the case because the effects of std::function::operator() don't imply that. Indeed, says that the effect of this call is

INVOKE(f, std::forward<ArgTypes>(args)..., R) (20.8.2), where f is the target object (20.8.1) of *this.

which basicallky says that std::function::operator() calls l_1.operator() and does nothing else (at least, nothing that is detectable).

(*) I'm putting details on how the interchange happens under the carpet but the idea remains valid. (E.g. what if the temporary holds a copy of l_1 and not a pointer to it?)

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