Suppose I have a callable type like so:

struct mutable_callable
    int my_mutable = 0;
    int operator()() { // Not const
        return my_mutable++;

Note that mutable_callable has a non-const operator() that modifies a member variable.....

Now suppose I create a std::function out of my type:

std::function<int()> foo = mutable_callable{};

Now I can do this:

void invoke(std::function<int()> const& z)

int main()
    invoke(foo); // foo changed.....oops

Now as far as I can tell std::functions operator() is const as per: https://en.cppreference.com/w/cpp/utility/functional/function/operator()

So my gut feeling is that you shouldn't be able to do this.....

But then looking at: https://en.cppreference.com/w/cpp/utility/functional/function/function

This doesn't seem to put any constraints on whether or not the callable type has a constant operator()......

So my question is this: I am correct in assuming that std::function<int()> const& is essentially the same thing as std::function<int()>& that is there is no actually difference between the behavior of the two......and if that is the case why is it not const correct?

  • @MaxLanghof No.....std::function has the equivalent to a struct a{ std::any x; }; in it..... – DarthRubik Dec 4 '19 at 15:33
  • Here is a small snippet of the internals of the MSVC std::function implementation: i.stack.imgur.com/eNenN.png where using _Ptrt = _Func_base<_Ret, _Types...>. I rest my case. – Max Langhof Dec 4 '19 at 15:36

This boils down to the same as struct A { int* x; };, where in a const A a; you can modify the value of *(a.x) (but not where it points to). There is a level of indirection in std::function (from the type erasure) through which const is not propagated.

And no, std::function<int()> const& f is not pointless. In a std::function<int()>& f you would be able to assign a different functor to f, which you cannot do in the const case.

  • Yup.....that actually makes a lot of sense.....still confusing at first glance though – DarthRubik Dec 4 '19 at 15:38
  • I believe it's a design flaw. This indirection should be an implementation detail transparent to the user, and the constness could be propagated using some metaprogramming. – Igor R. Dec 4 '19 at 15:49
  • @IgorR. Yes, the constness could be propagated. std::vector does this, std::unique_ptr doesn't. I feel std::function is not really about expressing invariants of the functor state though. Maybe we could repurpose abominable function types (i.e. std::function<int() const>) to distinguish? – Max Langhof Dec 4 '19 at 16:07
  • unique_ptr should not propagate constness, as the regular pointer does not. And std::function<int() const> wouldn't compile. – Igor R. Dec 4 '19 at 16:41
  • 1
    @IgorR. I know. My point was that some parts of the standard library do it and some others don't. Which category std::function should fall into is not clear to me. And the std::function<int() const> was a hypothetical - of course it doesn't compile now, but would it satisfy e.g. the OP here if that could be made valid, expressing "can only be assigned functors with a operator() const (or stateless ones)"? (even if behind the scenes that would be quite atrocious, due to using abominable function types)? – Max Langhof Dec 4 '19 at 16:58

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