7

From what I understand, std::forward<T>(x) is equivalent to static_cast<T&&>(x).

But from what I saw, static_cast<T>(x) seems to do the same thing, as can be seen in the following code

My question is therefore why std::forward<T> is implemented as static_cast<T&&>(x), and not static_cast<T>(x), if both have the same effect?

  • 1
    You didn't try with int&. – Quentin Sep 27 '15 at 9:45
  • @Quentin In that case, it always returns an lvalue. – Mikrosaft Sep 27 '15 at 9:47
  • static_cast<T> would create a copy of rvalues – Piotr Skotnicki Sep 27 '15 at 9:48
  • because you want to forward references but not values – Nevermore Sep 27 '15 at 9:49
  • Try it with a class where you will instrument the copy and move ctors to produce output, and observe the differences. – Angew Sep 27 '15 at 9:55
12

Because perfect forwarding allows to pass both r-value references and l-value references. This is done via reference collapsing:

T = int    --> T&& = int&&
T = int&   --> T&& = int& && = int&
T = int&&  --> T&& = int&& && = int&&

In your example with static_cast<T> you're simply losing r-value references. It works fine for primitive types (because passing int is usually copying a CPU register value), but awful for complex types because it leads to creating temporary object through copy ctors.

  • I just checked it, and it is in fact calls the copy constructor for rvalue's. But why? I read that if we call func() with an rvalue, T is deduced to be int&&, so static_cast<T>(x) would become static_cast<int&&>(x). So why it creates a copy? – Mikrosaft Sep 27 '15 at 9:56
  • 2
    static_cast<T> can return a reference: the answer above implies it cannot. Can you clarify that the problem only occurs in one "case"? – Yakk - Adam Nevraumont Sep 27 '15 at 9:58
  • @Mikrosaft: no, T cannot be deduced to int&&, it only can be either int or int&. – myaut Sep 27 '15 at 10:05
  • @myaut It makes perfect sense now. Thank you! – Mikrosaft Sep 27 '15 at 10:10
2

If T&& is an rvalue reference, then T is a value, then static_cast<T> makes a copy not a rvalue reference.

That copy will bind to rvalue references (just like the reference), but copy/move ctors could be needlessly called, and it is not a candidate for elision.

static_cast<T&&> will meanwhile just cast to an rvalue reference.

They are otherwise identical.

0

I agree with Yakk, but it's worse than that.

void foo(const std::vector<int> &vec);

template<typename T>
void callFoo(T &&data)
{
    foo(static_cast<T>(data));
}

int main()
{
    callFoo(std::vector<int>{/*...*/});
}

This will always create a copy. The vector is not moved because data, as an expression, is an lvalue of type std::vector<int>, even though the substituted type is std::vector<int>&&. Note that T is std::vector<int>, not std::vector<int> &&. Moral of the story: Use the standard library, it does the right thing and the name forward also captures the intention far better than static_cast<something>.

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