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Consider the situation where a function template needs to forward an argument while keeping it's lvalue-ness in case it's a non-const lvalue, but is itself agnostic to what the argument actually is, as in:

template <typename T>
void target(T&) {
    cout << "non-const lvalue";

template <typename T>
void target(const T&) {
    cout << "const lvalue or rvalue";

template <typename T>
void forward(T& x) {

When x is an rvalue, instead of T being deduced to a constant type, it gives an error:

int x = 0;
const int y = 0;

forward(x); // T = int
forward(y); // T = const int
forward(0); // Hopefully, T = const int, but actually an error
forward<const int>(0); // Works, T = const int

It seems that for forward to handle rvalues (without calling for explicit template arguments) there needs to be an forward(const T&) overload, even though it's body would be an exact duplicate.

Is there any way to avoid this duplication?

share|improve this question
If you are overloading on lvaluenes like this you deserve to be shot. – Yttrill Jan 2 '11 at 14:49
up vote 5 down vote accepted

This is a known problem and the purpose of rvalue references in C++0x. The problem has no generic solution in C++03.

There is some archaic historical reason why this occurs that is very pointless. I remember asking once and the answer depressed me greatly.

share|improve this answer
I am one of the people responsible for this sound rule. Deduction of type variables may only calculate value types. "const T" is not a value type. The duplication this requires is not pointless but semantically essential. In case you aren't aware of it, an rvalue never has "const" type, they're actually quite mutable. Dag Brueck of Sweden is responsible for that one, its so you can call g (f(x).modify()) which is needed to properly establish some values. – Yttrill Jan 2 '11 at 14:17
@Ytt: What exactly do you mean by "value type" here? – fredoverflow Jan 2 '11 at 14:21
@Yttrill: Right. So rvalues are perfectly mutable- but they can't bind to mutable references. So if you have g(f(x).modify()) it's perfectly fine, but you could never have g(f(x)) where g calls modify itself. I'm not really sure that you're presenting an argument against my suggestion that this state of affairs was ridiculous. – Puppy Jan 2 '11 at 14:41
The type of a value. Basically no top level const or reference. Pointers are values though, so "int const*" is a value type but "int const" is not. – Yttrill Jan 2 '11 at 14:44
@Yttrill: I think you're missing the point here. The question is not wether cv-qualifiers or reference-ness should be a part of a typename parameter value - the fact is that they are. The question is, given that, what's so essential about rvalues not being deduced "correctly" in this context? – uj2 Jan 2 '11 at 15:19

In general, this nasty problem with templates ought to require duplication because the semantics where a variable is const or not, or a reference or not, are quite distinct.

The C++11 solution to this is "decltype" but it is a bad idea because all it does is compound and already broken type system.

No matter what the Standard or the Committee says, "const int" is not and will never be a type. Nor will "int&" ever be a type. Therefore a type parameter in a template should never be allowed to bind to such non-types, and thankfully for deduction this is the case. Unfortunately you can still explicitly force this unprincipled substitution.

There are some idiotic rules which try to "fix" this problem, such as "const const int" reducing to "const int", I'm not even sure what happens if you get "int & &": remember even the Standard doesn't count "int&" as a type, there is a "int lvalue" type but that's distinct:

int x;       // type is lvalue int
int &y = x;  // type is lvalue int

The right solution to this problem is actually quite simple: everything is a mutable object. Throw out "const" (it isn't that useful) and throw away references, lvalues and rvalues. It's quite clear that all class types are addressable, rvalue or not (the "this" pointer is the address). There was a vain attempt by the committee to prohibit assigning to and addressing rvalues.. the addressing case works but is easily escaped with a trivial cast. The assignment case doesn't work at all (because assignment is a member function and rvalues are non-const, you can always assign to a class typed rvalue).

Anyhow the template meta-programming crowd have "decltype" and with that you can find the encoding of a declaration including any "const" and "&" bits and then you can decompose that encoding using various library operators. This couldn't be done before because that information is not actually type information ("ref" is actually storage allocation information).

share|improve this answer
"and thankfully for deduction this is the case". In the example, forward(y) deduces const int for T. – uj2 Jan 2 '11 at 14:47
(1) "const int is not... a type"? It clearly is a type in all versions of C++, so I take it you mean it should not be a type, in some ideal hypothetical world -- right? (2) Template argument deduction certainly can infer const int or int&, don't know what you're on about there. (3) When you say the solution is "everything is a mutable object", are you proposing a change to the C++ language? I can only assume so, but I initially thought you were advocating using just a subset of C++ that avoids const... – j_random_hacker Jan 2 '11 at 14:56
... but that won't work for forwarding because T& and T are now your only possible alternatives, and T& can't match an rvalue, while T will be deduced as a non-reference type, so it won't work for functions that need to modify the passed-in value. – j_random_hacker Jan 2 '11 at 14:58
"const int" is not a type "despite what the Standard says". So you can't cite the Standard here. It isn't a type. What constititues a type is determined by the theory of types, not by a standards document. – Yttrill Jan 2 '11 at 15:16
And no, you cannot infer "const int" from an top level argument. You might if the function was f(T*) called with an int const*, so you're right, I may have mistated the rules. Grrr .. that should be allowed. – Yttrill Jan 2 '11 at 15:18

When x is an rvalue

But x is never an rvalue, because names are lvalues.

Is there any way to avoid this duplication?

There is a way in C++0x:

#include <utility>

template <typename T>
void forward(T&& x)   // note the two ampersands

Thanks to reference collapsing rules, the expression std::forward<T>(x) is of the same value-category as the argument to your own forward function.

share|improve this answer
apologies! Will fix, but you have to edit your post first (SO rules, you can't change a vote unless the post is edited, I tried). – Yttrill Jan 2 '11 at 16:12

Assuming there are k arguments, as I understand it the only "solution" in C++03 is to manually write out 2^k forwarding functions taking every possible combination of & and const& parameters. For illustration, imagine that target() actually took 2 parameters. You would then need:

template <typename T>
void forward2(T& x, T& y) {
    target(x, y);

template <typename T>
void forward2(T& x, T const& y) {
    target(x, y);

template <typename T>
void forward2(T const& x, T& y) {
    target(x, y);

template <typename T>
void forward2(T const& x, T const& y) {
    target(x, y);

Obviously this gets very unwieldy for large k, hence rvalue references in C++0x as other answers have mentioned.

share|improve this answer
You should never do it so this is never needed. – Yttrill Jan 2 '11 at 14:49
@Yttrill: Huh? It would be very useful to have the ability to forward an arbitrary function call. See the "Motivating Examples" section at the top of – j_random_hacker Jan 2 '11 at 15:00
@j_random_hacker: Of course I agree forwarding is useful. What is not useful is overloading on non-value types. You should NEVER have two functions of the same name where arguments differ only in "const" or "ref" because the semantics are different, so the names should be too. – Yttrill Jan 2 '11 at 15:10
Just to ensure understanding: in the OP's example we have precisely this extremely bad practice: two functions called target, one accepting a T& and the other a T const&. I have no sympathy for anyone writing such functions, and therefore none for people trying to use a common template to target one or the other based on its arguments decltype. – Yttrill Jan 2 '11 at 15:12
@Yttrill: I agree that overloading on non-value types is a bad idea. But sometimes you need to be able to forward to an unknown function whose argument types you don't know (that is, they could be by-value or by-reference), in which case you still need a perfect forwarding mechanism. E.g. imagine all the forward2() function templates above were methods in a class templated on U, which has a member U u;, and the calls to target(x, y) above were changed to, y);. Now we don't know what argument flavour U::target() expects, so the 4 overloads are necessary. – j_random_hacker Jan 2 '11 at 15:20

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