Why is template argument deduction disabled with std::forward?
In VS2010 std::forward is defined as such:
template<class _Ty> inline
_Ty&& forward(typename identity<_Ty>::type& _Arg)
{ // forward _Arg, given explicitly spec开发者_运维技巧ified type parameter
return ((_Ty&&)_Arg);
}
identity
appears to be used solely to disable template argument deduction. What's the point of purposefully disabling it in this case?
If you pass an rvalue reference to an object of type X
to a template function that takes type T&&
as its parameter, template argument deduction deduces T
to be X
. Therefore, the parameter has type X&&
. If the function argument is an lvalue or const lvalue, the compiler deduces its type to be an lvalue reference or const lvalue reference of that type.
If std::forward
used template argument deduction:
Since objects with names are lvalues
the only time std::forward
would correctly cast to T&&
would be when the input argument was an unnamed rvalue (like 7
or func()
). In the case of perfect forwarding the arg
you pass to std::forward
is an lvalue because it has a name. std::forward
's type would be deduced as an lvalue reference or const lvalue reference. Reference collapsing rules would cause the T&&
in static_cast<T&&>(arg)
in std::forward to always resolve as an lvalue reference or const lvalue reference.
Example:
template<typename T>
T&& forward_with_deduction(T&& obj)
{
return static_cast<T&&>(obj);
}
void test(int&){}
void test(const int&){}
void test(int&&){}
template<typename T>
void perfect_forwarder(T&& obj)
{
test(forward_with_deduction(obj));
}
int main()
{
int x;
const int& y(x);
int&& z = std::move(x);
test(forward_with_deduction(7)); // 7 is an int&&, correctly calls test(int&&)
test(forward_with_deduction(z)); // z is treated as an int&, calls test(int&)
// All the below call test(int&) or test(const int&) because in perfect_forwarder 'obj' is treated as
// an int& or const int& (because it is named) so T in forward_with_deduction is deduced as int&
// or const int&. The T&& in static_cast<T&&>(obj) then collapses to int& or const int& - which is not what
// we want in the bottom two cases.
perfect_forwarder(x);
perfect_forwarder(y);
perfect_forwarder(std::move(x));
perfect_forwarder(std::move(y));
}
Because std::forward(expr)
is not useful. The only thing it can do is a no-op, i.e. perfectly-forward its argument and act like an identity function. The alternative would be that it's the same as std::move
, but we already have that. In other words, assuming it were possible, in
template<typename Arg>
void generic_program(Arg&& arg)
{
std::forward(arg);
}
std::forward(arg)
is semantically equivalent to arg
. On the other hand, std::forward<Arg>(arg)
is not a no-op in the general case.
So by forbidding std::forward(arg)
it helps catch programmer errors and we lose nothing since any possible use of std::forward(arg)
are trivially replaced by arg
.
I think you'd understand things better if we focus on what exactly std::forward<Arg>(arg)
does, rather than what std::forward(arg)
would do (since it's an uninteresting no-op). Let's try to write a no-op function template that perfectly forwards its argument.
template<typename NoopArg>
NoopArg&& noop(NoopArg&& arg)
{ return arg; }
This naive first attempt isn't quite valid. If we call noop(0)
then NoopArg
is deduced as int
. This means that the return type is int&&
and we can't bind such an rvalue reference from the expression arg
, which is an lvalue (it's the name of a parameter). If we then attempt:
template<typename NoopArg>
NoopArg&& noop(NoopArg&& arg)
{ return std::move(arg); }
then int i = 0; noop(i);
fails. This time, NoopArg
is deduced as int&
(reference collapsing rules guarantees that int& &&
collapses to int&
), hence the return type is int&
, and this time we can't bind such an lvalue reference from the expression std::move(arg)
which is an xvalue.
In the context of a perfect-forwarding function like noop
, sometimes we want to move, but other times we don't. The rule to know whether we should move depends on Arg
: if it's not an lvalue reference type, it means noop
was passed an rvalue. If it is an lvalue reference type, it means noop
was passed an lvalue. So in std::forward<NoopArg>(arg)
, NoopArg
is a necessary argument to std::forward
in order for the function template to do the right thing. Without it, there's not enough information. This NoopArg
is not the same type as what the T
parameter of std::forward
would be deduced in the general case.
Short answer:
Because for std::forward
to work as intended(, i.e. to faitfully pass the original type info), it is meant to be used INSIDE TEMPLATE CONTEXT, and it must use the deduced type param from the enclosing template context, instead of deducing the type param by itself(, since only the enclosing templates have the chance to deduce the true type info, this will be explained in the details), hence the type param must be provided.
Though using std::forward
inside non-template context is possible, it is pointless(, will be explained in the details).
And if anyone dares to try implementing std::forward
to allow type deducing, he/she is doomed to fail painfully.
Details:
Example:
template <typename T>
auto someFunc(T&& arg){ doSomething(); call_other_func(std::forward<T>(para)); }
Observer that arg
is declared as T&&
,( it is the key to deduce the true type passed, and) it is not a rvalue reference, though it has the same syntax, it is called an universal reference (Terminology coined by Scott Meyers), because T
is a generic type, (likewise, in string s; auto && ss = s;
ss is not a rvalue reference).
Thanks to universal reference, some type deduce magic happens when someFunc
is being instantiated, specifically as following:
- If an rvalue object, which has the type
_T
or_T &
, is passed tosomeFunc
,T
will be deduced as_T &
(, yeah, even if the type ofX
is just_T
, please read Meyers' artical); - If an rvalue of type
_T &&
is passed tosomeFunc
,T
will be deduced as_T &&
Now, you can replace T
with the true type in above code:
When lvalue obj is passed:
auto someFunc(_T & && arg){ doSomething(); call_other_func(std::forward<_T &>(arg)); }
And after applying reference collapse rule(, pls read Meyers' artical), we get:
auto someFunc(_T & arg){ doSomething(); call_other_func(std::forward<_T &>(arg)); }
When rvalue obj is passed:
auto someFunc(_T && && arg){ doSomething(); call_other_func(std::forward<_T &&>(arg)); }
And after applying reference collapse rule(, pls read Meyers' artical), we get:
auto someFunc(_T && arg){ doSomething(); call_other_func(std::forward<_T &&>(arg)); }
Now, you can guess what std::forwrd does eseentially is just static_cast<T>(para)
(, in fact, in clang 11's implementation it is static_cast<T &&>(para)
, which is the same after applying reference collapsing rule). Everything works out fine.
But if you think about let std::fowrd deducing the type param by itself, you'll quickly find out that inside someFunc
, std::forward
literally IS NOT ABLE TO deduce the original type of arg
.
If you try to make the compiler do it, it will never be deduced as _T &&
(, yeah, even when arg
is bind to an _T &&
, it is still an lvaule obj inside someFunc
, hence can only be deduceed as _T
or _T &
.... you really should read Meyers' artical).
Last, why should you only use std::forward
inside templates? Because in non-templates context, you know exactly what type of obj you have. So, if you have an lvalue bind to an rvalue reference, and you need to pass it as an lvaule to another function, just pass it, or if you need to pass it as rvalue, just do std::move
. You simply DON'T NEED std::forward inside non-template context.
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