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I have this code:

template <typename T, void (*f)(T*)>
class callfn
{
  public:
  void operator()(T* obj) const
  {
    f(obj);
  }
};

void call(int* foo) {}

void test()
{
  callfn<int, call> fun;
  fun(1);
}

Which tends to work fine. the type callfn is however used all over the place, And I'd much prefer if I could call it like this

callfn<call> fun;

instead, without modifying the type of call Is it possible to arrange the callfn template/templates in such a way that it can deduce the T type from the type of f?

share|improve this question
    
what exactly are you doing with this? RN it just makes a functor that is essentially identical to the function itself – aaronman Nov 8 '13 at 5:25
    
The goal is to use it as a deleter function for std::unique_ptr as a type so I can pass in a function as the deleter, and not take the 4 byte overhead of actually passing in a function* – Arelius Nov 8 '13 at 5:37
    
Why would this not have any overhead, if anything a functor would have a higher overhead, I would just use the fp – aaronman Nov 8 '13 at 5:38
    
Also what's wrong with std::function, if your so against fp's – aaronman Nov 8 '13 at 5:39
    
Sorry, let me try to clarify. void mfree(MObj* o); std::unique_ptr<MObj, callfn<MObj, mfree> mptr; assert(sizeof(mptr) == sizeof(MObj*)); I hope that adds some clarity. – Arelius Nov 8 '13 at 5:40
up vote 1 down vote accepted

No you need to know the args for a struct or class only functions have template type deduction in c++.

Paper n3602 seems to address this so it seems your not the only one who finds this annoying (me too). I don't know if it's going to be included but the paper at least means other people are thinking of it. n6301 will be able to eliminate the redundant typename you have for the non-type template param.

Another thing (also in c++14) is make_unique which will be in the next standard. It is also probably relatively easy to code yourself.

As I noted in my comment it's unclear what exactly your trying to achieve with this, and if having to write the extra type is actually a barrier.

Since you made it clear in your comments that you need this to make a deleter for a unique_ptr I'm not sure what's wrong with.

std::unique_ptr<int,void(*)(int*)> ptr(int_ptr,deleter);
share|improve this answer
    
The goal of this is to not only make a deleter, but a deleter that doesn't take up any extra space per pointer, just like default_deleter does, yet with support for arbitrary functions. – Arelius Nov 8 '13 at 6:08
    
@Arelius just use decltype, I'm gonna add a solution with that – aaronman Nov 8 '13 at 6:10
    
@Arelius actually it really doesn't help that much, so you already have your solution but you just wanna type like 5 fewer letters is that the gist of it? – aaronman Nov 8 '13 at 6:13
    
Correct, 5, or more or less depending on the length of an identifier. – Arelius Nov 8 '13 at 6:14
    
It looks like this is something not possible, but actually addressed in n3601 I think that seems to be a more applicable paper. – Arelius Nov 8 '13 at 6:18

Adding on top of aaronman's post. Although you can't do with a template class alone, with some helpers, including a macro, it's possible:

template <typename T>
T deduce(void(*)(T*));

#define CALLFN(f) callfn<decltype(deduce(f)), f> 

Example of usage:

CALLFN(call) fun; // instead of 'callfn<call> fun;' as asked

However, from the OP's comments this just a piece of a problem whose solution without this piece seems simpler.

If I understand it correctly, you want to create a std::unique_ptr for a certain type T with a custom function deleter f (of type void (*)(T*)) but you don't want the overhead of carring a function pointer in the std::unique_ptr. For instance, consider:

class MObj { /* ... */ };
void mfree(MObj*) { /* ... */ }

As said in an OP's comment we typically have

std::unique_ptr<MObj, void(*)(MObj*)> p1(nullptr, mfree);
assert(sizeof(p1) == sizeof(MObj*) * 2);

but using callfn we can save space:

std::unique_ptr<MObj, callfn<MObj, mfree>> p2;
assert(sizeof(p2) == sizeof(MObj*));

I believe the only annoyance with the solution above is the need of typing callfn and MObj twice. So, what about this:

template <typename T, void (*f)(T*)>
using light_unique_ptr = std::unique_ptr<T, callfn<T, f>>;

light_unique_ptr<MObj, mfree> p3; // 1
assert(sizeof(p3) == sizeof(MObj*));

I also understand (maybe I'm wrong) that the intent is having something even shorter like

lighter_unique_ptr<mfree> p4; // 2
assert(sizeof(p4) == sizeof(MObj*));

and leave the compiler to deduce the type of the pointed object from mfree. As I indicated, this can be done with a macro but I don't think this is a good thing for two reasons:

  1. It doesn't work if we have different overloads for mfree (say void mfree(MObj*) and void mfree(Foo*)).
  2. A user will normally expect to see the pointed type of a std::unique_ptr in its instantiation and (eventually) its deleter. Line 1 above does show the type (MObj) but line 2 doesn't. Not seeing the type might be confusing for some.

I agree that the second point above is arguable (similar to the should-I-use-auto debate).

share|improve this answer
1  
That's some ballsy programming right there – aaronman Nov 8 '13 at 7:40
    
I like this solution, I may not actually end up using it just to avoid the macro. but it's indeed a very clever solution. – Arelius Nov 8 '13 at 20:35
    
Couldn't you define deduce as a private class-static function within callfn, set up a member type-alias to decltype( deduce(f) ), and use (a pointer to) that type as the input to operator()? (You would use "template <typename f>" as the header for callfn, seeing if f fails to match in the call to deduce.) – CTMacUser Nov 8 '13 at 22:56
    
@CTMacUser I'm not sure I understand you correctly but it seems to me that this wouldn't work. If we have template <typename f> class callfn, then callfn would need a type to be instantiaded with. However, the deleter, say mfree, is a function of a certain type but it's not a type itself. Therefore, callfn<mfree> wouldn't compile. – Cassio Neri Nov 9 '13 at 1:01
    
@CassioNeri, yeah, I just tried it. f is a value (a function pointer) not a type. So we would have to replace the "typename" with an actual function type, but we can't since we want that to be variable. We can't get around having two template arguments, short of a macro like CALLFN. – CTMacUser Nov 9 '13 at 7:04

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