A lot of places in the STL and elsewhere you see code like this:
template <typename Func>
void foo(Func f)
{
// ...
f();
}
i.e. the callable parameter f is passed by (copy of) value. Why is this seemingly preferred over typing the parameter as Func&, const Func&, or Func&&?
The simple reason is that you can turn a value of a deduced type to use reference semantics, e.g., by passing std::ref(x) instead of x to the function. Obviously, for things which have more interesting operations than a function call operator you may need to use a custom wrapper but in general it is straight forward to write a wrapper for a class which give reference semantics to a value type.
On the other hand, once you are in a reference world, there is no way to undo this referencing under the control of the caller. Any reasonable generic function which receives a reference for an object cannot assume that the object behind this reference actually has exactly the referenced type but rather has to assume that the objects would get sliced to their base class. Thus, it can't just copy an argument received, for example, as Func& to a Func by copying it.
Taking these two realizations together pass by value for deduced types is the obvious choice for entities which may be copied in the implementation of the generic function. Note that this reasoning applies generally to arguments passed to generic functions not just to callable arguments.
Func fis a pointer to a function, which resides in the (read-only) code section of the executable image, so there's really no point in passingFunc&, since: 1. the amount of data copied into the stack would be identical (size of a memory address) in both cases. 2. You would not be able to change that reference (had you passed it as reference) anyway.Func fis not necessarily a pointer to a function. It could be a functor as well. Also,Func && fis much better thanFunc f, in general.Func&& fis only better thanFunc fiffis quite obviously forwarded and entity usingFunc&&is clear about passingfon (obviously usingstd::forward<Func>(f)in some form). That is the case for function adaptors but is not the case, e.g., for algorithms.T&&in a context you'll get a reference in all cases and you can't copy the object because you can't assume that the deduced type based on the static type of the argument matches the actually used dynamic type. You can make this assumption when taking arguments by value, though. Also, the compiler can't make the assumption that the object is local and may need to follow the indirection (I don't have benchmarks showing this effect, though: I haven't tried; the semantic argument should be sufficient...).