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In C++03, Boost's Foreach, using this interesting technique, can detect at run-time whether an expression is an lvalue or an rvalue. (I found that via this StackOverflow question: Rvalues in C++03 )

Here's a demo of this working at run-time

(This is a more basic question that arose while I was thinking about this other recent question of mine. An answer to this might help us answer that other question.)

Now that I've spelled out the question, testing rvalue-ness in C++03 at compile-time, I'll talk a little about the things I've been trying so far.

I want to be able to do this check at compile-time. It's easy in C++11, but I'm curious about C++03.

I'm trying to build upon their idea, but would be open to different approaches also. The basic idea of their technique is to put this code into a macro:

true ? rvalue_probe() : EXPRESSION;

It is 'true' on the left of the ?, and therefore we can be sure that EXPRESSION will never be evaluated. But the interesting thing is that the ?: operator behaves differently depending on whether its parameters are lvalues or rvalues (click that link above for details). In particular, it will convert our rvalue_probe object in one of two ways, depending on whether EXPRESSION is an lvalue or not:

struct rvalue_probe
{
    template< class R > operator       R () { throw "rvalue"; }
    template< class L > operator       L & () const { throw "lvalue"; }
    template< class L > operator const L & () const { throw "const lvalue"; }
};

That works at runtime because the thrown text can be caught and used to analyze whether the EXPRESSION was an lvalue or an rvalue. But I want some way to identify, at compile-time, which conversion is being used.

Now, this is potentially useful because it means that, instead of asking

Is EXPRESSION an rvalue?

we can ask:

When the compiler is compiling true ? rvalue_probe() : EXPRESSION, which of the two overloaded operators, operator X or operator X&, is selected?

( Ordinarily, you could detect which method was called by changing the return types and getting the sizeof it. But we can't do that with these conversion operators, especially when they're buried inside the ?:. )

I thought I might be able to use something like

is_reference< typeof (true ? rvalue_probe() : EXPRESSION) > :: type

If the EXPRESSION is an lvalue, then the operator& is selected and I hoped that the whole expression would then be a & type. But it doesn't seem to work. ref types and non-ref types are pretty hard (impossible?) to distinguish, especially now that I'm trying to dig inside a ?: expression to see which conversion was selected.

Here's the demo code pasted here:

#include <iostream>
using namespace std;
struct X {
        X(){}
};

X x;
X & xr = x;
const X xc;

      X   foo()  { return x; }
const X   fooc() { return x; }
      X & foor()  { return x; }
const X & foorc() { return x; }

struct rvalue_probe
{
        template< class R > operator       R () { throw "rvalue"; }
        // template< class R > operator R const () { throw "const rvalue"; } // doesn't work, don't know why
        template< class L > operator       L & () const { throw "lvalue"; }
        template< class L > operator const L & () const { throw "const lvalue"; }
};

typedef int lvalue_flag[1];
typedef int rvalue_flag[2];
template <typename T> struct isref     { static const int value = 0; typedef lvalue_flag type; };
template <typename T> struct isref<T&> { static const int value = 1; typedef rvalue_flag type; };

int main() {
        try{ true ? rvalue_probe() : x;       } catch (const char * result) { cout << result << endl; } // Y lvalue
        try{ true ? rvalue_probe() : xc;      } catch (const char * result) { cout << result << endl; } // Y const lvalue
        try{ true ? rvalue_probe() : xr;      } catch (const char * result) { cout << result << endl; } // Y       lvalue
        try{ true ? rvalue_probe() : foo();   } catch (const char * result) { cout << result << endl; } // Y rvalue
        try{ true ? rvalue_probe() : fooc();  } catch (const char * result) { cout << result << endl; } // Y rvalue
        try{ true ? rvalue_probe() : foor();  } catch (const char * result) { cout << result << endl; } // Y lvalue
        try{ true ? rvalue_probe() : foorc(); } catch (const char * result) { cout << result << endl; } // Y const lvalue

}

(I had some other code here at the end, but it's just confusing things. You don't really want to see my failed attempts at an answer! The above code demonstrates how it can test lvalue-versus-rvalue at runtime.)

share|improve this question
    
What is foo's return type? –  hvd Jan 31 '12 at 18:44
    
@hvd, I've updated the end of the question accordingly. I should have said fooref, not foo. But anyway, typeof still thinks that true ?: fooref() : fooref() is not a reference. –  Aaron McDaid Jan 31 '12 at 18:55
    
@hvd, ... I checked typeof(x) and typeof(xr) also and they are giving the same type, this doesn't make sense to me. There appear to be inconsistencies in typeof. I get the right behaviour with typeof(int&), but it doesn't do the same thing with typeof(xr). –  Aaron McDaid Jan 31 '12 at 18:58
    
The type and lvalue-ness of x and xr is the same, so I'm assuming that's why typeof's result is the same. There is subtly different behaviour with decltype that might help you out, but your version of g++ doesn't support it. –  hvd Jan 31 '12 at 19:02
    
You try to invent standard is_lvalue_reference/is_rvalue_reference? Or I miss something. –  Andrew Jan 31 '12 at 19:25

2 Answers 2

up vote 6 down vote accepted

It took some effort, but here's a tested and working is_lvalue macro that correctly handles const struct S function return types. It relies on const struct S rvalues not binding to const volatile struct S&, while const struct S lvalues do.

#include <cassert>

template <typename T>
struct nondeducible
{
  typedef T type;
};

char (& is_lvalue_helper(...))[1];

template <typename T>
char (& is_lvalue_helper(T&, typename nondeducible<const volatile T&>::type))[2];

#define is_lvalue(x) (sizeof(is_lvalue_helper((x),(x))) == 2)

struct S
{
  int i;
};

template <typename T>
void test_()
{
  T a = {0};
  T& b = a;
  T (* c)() = 0;
  T& (* d)() = 0;
  assert (is_lvalue(a));
  assert (is_lvalue(b));
  assert (!is_lvalue(c()));
  assert (is_lvalue(d()));
}

template <typename T>
void test()
{
  test_<T>();
  test_<const T>();
  test_<volatile T>();
  test_<const volatile T>();
}

int main()
{
  test<int>();
  test<S>();
}

Edit: unnecessary extra parameter removed, thanks Xeo.

Edit again: As per the comments, this works with GCC but relies on unspecified behaviour in C++03 (it's valid C++11) and fails some other compilers. Extra parameter restored, which makes it work in more cases. const class rvalues give a hard error on some compilers, and give the correct result (false) on others.

share|improve this answer
2  
wow, that's a nice trick. –  Johannes Schaub - litb Jan 31 '12 at 23:31
    
Nevermind my last comment, Clang spews way to many errors with that for some reason... Clang also errors on your previous version, with the complete error shown here. That might be a Clang bug, though. –  Xeo Jan 31 '12 at 23:50
    
Ok, all of comeau, gcc and clang accept also function lvalues with Xeo's version. That clang and comeau rejects that code has to do with a clarification of C++11. They clarified that only const non-volatile references can bind to rvalues. C++03 just said that "binding a reference to non-const to an rvalue" is not possible. C++11 added the non-volatile part. That they still reject it in C++03 is because the reference binding itself is still ill-formed, even if overload resolution itself accepts the conversion. –  Johannes Schaub - litb Jan 31 '12 at 23:55
    
Why does this work? Is it because rvalues shouldn't have any other references to them and hence are less 'volatile' than lvalues? I never really paid attention to volatile before - thanks for motivating me to read up on it! –  Aaron McDaid Jan 31 '12 at 23:56
    
@JohannesSchaub-litb Is that a clarification or a change in behaviour? If this code works with GCC in C++03 mode because it implements the C++11 semantics, that's not something I'm happy with :) –  hvd Feb 1 '12 at 0:01

The address-of operator (&) can only be used with an lvalue. So if you used it in an SFINAE test, you could distinguish at compile-time.

A static assertion could look like:

#define STATIC_ASSERT_IS_LVALUE(x) ( (sizeof &(x)), (x) )

A trait version might be:

template<typename T>
struct has_lvalue_subscript
{
    typedef char yes[1];
    typedef char no[2];

    yes fn( char (*)[sizeof (&(((T*)0)->operator[](0))] );
    no fn(...);
    enum { value = sizeof(fn(0)) == 1 };
};

and could be used like

has_lvalue_subscript< std::vector<int> >::value

(Warning: not tested)

I can't think of any way to test an arbitrary expression valid in the caller's context, without breaking compilation on failure.

share|improve this answer
    
Can the address-of operator not be used with rvalues of class type that have their own operator& function? –  hvd Jan 31 '12 at 20:01
    
I like this. It's not a full solution yet, but it is correct. I'm experimenting a little with this now. –  Aaron McDaid Jan 31 '12 at 22:08
    
@hvd: It's hard to say what result you want for a class weird enough to overload operator&. It probably is trying to transparently wrap an lvalue, in which case maybe this test should say it IS an lvalue. –  Ben Voigt Jan 31 '12 at 22:41
    
I think I envisage having a macro called STATIC_ASSERT_IS_LVALUE(x) which will cause a compilation failure if x isn't an lvalue (and which will also evaluate to x). Taking the & would be good enough for me. If we can just write up the assertion, then I think I'll accept this. What about using the comma operator? #define STATIC_ASSERT_IS_LVALUE(x) ( (typeof(&x) ) 0 , x) –  Aaron McDaid Jan 31 '12 at 22:59
    
... ultimately, it would be nice if it did something other than force a compilation error. For example, somebody might want a STATIC_ASSERT_IS_RVALUE instead. But the former would be good enough for me. –  Aaron McDaid Jan 31 '12 at 23:04

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