13

Given the following setup:

// ***** Library Code *****
#include <concepts>

template <std::invocable CbT>
struct delegated {
  explicit constexpr delegated(CbT cb) : cb_(std::move(cb)) {}

 private:
  [[no_unique_address]] CbT cb_;
};

// ***** User Code *****
#include <iostream>

namespace {
  inline constexpr void func() {}
}

struct MyFunc {
  constexpr void operator()() const {}
};


int main() {
    void (*func_ptr)() = func;

    auto from_func = delegated{func};
    auto from_func_ptr = delegated{func_ptr};
    auto from_lambda = delegated{[](){}};
    auto from_functor = delegated{MyFunc{}};

    std::cout << "func: " << sizeof(from_func) << "\n";
    std::cout << "func_ptr: " << sizeof(from_func_ptr) << "\n";
    std::cout << "lambda: " << sizeof(from_lambda) << "\n";
    std::cout << "functor: " << sizeof(from_functor) << "\n";
}

It produces, on GCC-x86-64 (See on godbolt):

func: 8        <----- Unfortunate
func_ptr: 8    <----- Fair enough
lambda: 1      <----- Neat
functor: 1     <----- Neat

None of this is particularly surprising.

However, it's frustrating that an undecayed lambda is preferable to using a function. And adding a note that delegated{[]{func();}} reduces the storage overhead is not exactly user-friendly, and makes for a very poor library interface.

Is there a way to do away with the storage overhead in the func case while maintaining a consistent user-facing API?

My current suspicion is that this is not possible without resorting to macros, on account of func not having, or decaying into, any type that would distinguish it from other functions with the same signature. I'm hoping that I overlooked something.

N.B. I get that something along the lines of delegated<func>() is a possibility, but unless I can prevent delegated{func} while still allowing delegated{func_ptr}, then that would be practically pointless.

Edit: To clarify the context a little bit: I am writing delegated in a library, and I don't want users of said library to have to worry about this. Or at least have the process be compiler-assisted instead of being documentation-dependant.

9
  • Would you be adverse to having a factory function, and use it like auto my_delegate = make_delegate(something);? Aug 25, 2021 at 16:53
  • @NathanOliver That would be great! (as long as it's not a macro) I tried a few things in that direction before posting the question but haven't had luck yet.
    – user4442671
    Aug 25, 2021 at 16:54
  • 2
    Where is this storage overhead occuring? Is it only occuring on the stack while calling? Because storing the lambda will require overhead much larger. Do you value the size of the instruction code at all? The cost there for lambdas will be larger than the cost of a single function pointer on the stack. In short, what practical* cost are you attempting to deal with?0 here? One number being bigger than another isn't a practical cost. Aug 25, 2021 at 19:39
  • 1
    @Frank So, a stateless lambda object must have which code is called be stored in the program code of all code that calls it. For a function pointer, the same calling code can be used for every calling code that uses it. If your optimized code is not actually following the pointer, your compiler is proving which pointer it is calling and skipping actually using the pointer. To me, this is extremely strong evidence that you putting that pointer on the heap is a design flaw. And multiple copies of a stateless lambda is ... pretty pointless? Aug 25, 2021 at 20:09
  • 1
    On the other hand, if you are doing type erasure of the delegated object (so the compiler doesn't know what the function does), it isn't tricky to handle function pointers in a way that saves you the overhead; especially if you are willing to hack the ABI. Because the process of erasing overhead has some wiggle room in it. Aug 25, 2021 at 20:15

3 Answers 3

5

There are no objects of function types. The type will be adjusted to be a function pointer, which is why you delegated{func} and delegated{func_ptr} are exactly the same thing and former cannot be smaller.

Wrap the function call inside a function object (lambda, if you so prefer) to avoid the overhead of the function pointer.


If you would like to prevent the accidental use of the adjusted/decayed function pointer case when user tries to pass a function, then you could use a deleted overload for function references. I don't know how that could be achieved with CTAD, but if you provide a function interface, it could be done like this:

constexpr auto
make_delegated(std::invocable auto CbT)
{
    return delegated{std::move(CbT)};
}

template<class... Args>
constexpr auto
make_delegated(auto (&cb)(Args...)) = delete;

Edit: Combining ideas with Human-Compiler's answer

template <auto CbT>
constexpr auto
make_delegated_fun() { 
  return delegated{ []{ CbT(); } };
}

constexpr auto
make_delegated(std::invocable auto CbT)
{
    return delegated{std::move(CbT)};
}

template<class... Args>
constexpr auto
make_delegated(auto (&cb)(Args...)) {
    // condition has to depend on template argument;
    // just false would cause the assert to trigger without overload being called.
    static_assert(!std::is_reference_v<decltype(cb)>, "please use make_delegated_fun");
};


auto from_func1 = make_delegated(func);        // fails to compile
auto from_func2 = make_delegated_fun<func>();  // OK
auto from_func_ptr = make_delegated(func_ptr); // OK, pointer overhead
auto from_lambda = make_delegated([](){});     // OK
auto from_functor = make_delegated(MyFunc{});  // OK

Caveat, this would prevent following, and the example wouldn't work using make_delegated_fun either so the message would be misleading. The example could easily be rewritten to use function pointers or capturing lambda though:

auto& fun_ref = condition ? fun1 : fun2;
make_delegated(fun_ref);       // fails to compile, suggests make_delegated_fun
make_delegated_fun<fun_ref>(); // fails to compile, not constexpr
make_delegated(&fun_ref);      // OK, pointer overhead
9
  • Just a heads-up that deleting the auto (&cb)(Args...) overload does not necessarily detect every use, though it's probably the closest approach possible. If anyone explicitly uses the form &func, then it will construct a delegated from a function-pointer -- despite the function itself being known at compile-time. Aug 25, 2021 at 17:22
  • @Frank Found an example that seems to work in my basic testing.
    – eerorika
    Aug 25, 2021 at 17:26
  • @Human-Compiler Yes, the use of function pointer is intentionally allowed when used explicitly. It's useful when the value isn't compiletime constant. I don't think detecting unnecessary use of &func would be easy within the language. Maybe achievable with static analysis.
    – eerorika
    Aug 25, 2021 at 17:29
  • Yeah, &func leading down the same path as any old function pointer is absolutely reasonable from my point of view.
    – user4442671
    Aug 25, 2021 at 17:30
  • Note that make_delegated with the static_assert sadly makes a program ill-formed, no diagnostic required, as it is a template specialization with no possible valid instantiation. Making the static assert seem to be dependent on the template argument fools the compiler, but the C++ standard is not fooled. It demands that all template functions can be instantiated with some set of arguments, no matter how "tricky" you get in attempting to fool the compiler. Aug 25, 2021 at 20:20
1

The only way to really remove the "storage" from a function like this is to use the value at compile-time. The only real way to accomplish this is through a non-type template argument.

A factory function could do this easily with little changes, and keeps the implementation simple. You just need to accept the callable object as a template non-type argument -- such as an auto parameter, so that its known at compile-time without any storage requirements.

One way to perform this is to just use your lambda-wrapping solution with the existing code:

template <auto Fn>
auto make_delegated() { 
  return delegated{ []{ Fn(); } };
}

Then the following works:

auto from_func = make_delegated<&func>();
std::cout << "func: " << sizeof(from_func) << "\n";

this yields the correct value:

func: 1

Live Example


As an alternative measure, you could also require the user to wrap the function itself in a sentinel type that carries the data:

template <auto Fn>
struct empty_func{
  auto operator()() { return Fn(); }
};

This would be almost equivalent to using a lambda, though the user instead only has to do:

auto from_func = delegated{empty_func<&func>{}};

The point is just that the function needs to be carried at compile-time somewhere.

3
  • Thanks for the answer. However I did mention in the question that for this to be a workable solution, it would need to come alongside something that prevents (or at least warn) users from using delegated{func}, which will be the path of least resistance.
    – user4442671
    Aug 25, 2021 at 17:02
  • Passing a function to a constructor argument changes it from being known at compile-time in the conventional sense as soon as it is used as a parameter -- so, strictly speaking, using a constructor for this is not possible without some change in flow. The only way to change this is to make the function to be passed as a template non-type template argument. If you want to warn on it, you could always mark a specific constructor for function pointers as deprecated with a warning to use the utility. Aug 25, 2021 at 17:05
  • @Frank I put up a separate alternative. The only real solution to remove the size will be to carry the function at compile-time, so an alternative is to use a sentinel-like wrapper struct that just holds it in the type. This isn't drastically different than using a lambda, and it still requires some changes to the caller -- but I'm not sure you can do much better than this without at least requiring the user to always use a different interface. You could always just make the user need to use a make_delegated factory everywhere so it remains consistent. Aug 25, 2021 at 17:12
1

Passing the function pointer as a template argument does not require any space at runtime. For example:

template <auto F>
struct delegated_erased {
    template <typename... argument_t>
    auto operator()(argument_t&&... argument){
        F(std::forward<argument_t>(argument)...);
    }
};
auto from_func = delegated_erased<func>{};
std::cout << "func: " << sizeof(from_func) << "\n"; // 1

With a helper function, you can combine this with your code:

template <typename result, typename ... argument>
delegated<result> make_delegated(result(&)(argument...)) = delete;

template <typename T>
delegated<T> make_delegated(T f) {
    return delegated{std::move(f)};
};

template <auto F>
delegated_erased<F> make_delegated(){
    return {};
}

Which allows you to do:

    auto from_func = make_delegated<func>();
    //auto from_func = make_delegated(func); // error: call to deleted function 'make_delegated'
    auto from_func_ptr = make_delegated(func_ptr);
    auto from_lambda = make_delegated([](){});
    auto from_functor = make_delegated(MyFunc{});
2
  • How would I use this with a lambda, function, std::function, function pointer, etc...?
    – user4442671
    Aug 25, 2021 at 16:53
  • You can use a helper function, see my updated answer. It's not the same API but it works Aug 25, 2021 at 17:25

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