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I'm told that, in C++03, temporaries are implicitly non-modifiable.

However, the following compiles for me on GCC 4.3.4 (in C++03 mode):

cout << static_cast<stringstream&>(stringstream() << 3).str();

How is this compiling?

(I am not talking about the rules regarding temporaries binding to references.)

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3  
You have incorrectly been told... const-ness is orthogonal to temporary-ness (lvalue vs rvalue-ness) –  David Rodríguez - dribeas Jun 24 '11 at 10:09
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@David: I should have been more careful with the question title, really. I really did mean "implicitly non-modifiable" rather than specifically "const". And as it turns out, to a point, this is exactly what they are. –  Lightness Races in Orbit Jun 24 '11 at 10:11
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Only temporaries of non user defined class type are implicitly non-modifiable: std::vector<int>().resize( 100 ); is perfectly valid, creates a temporary and modifies it (without the need for a cast as in your example). –  David Rodríguez - dribeas Jun 24 '11 at 10:21
    
@David: Read my answer, which contains a standard quote. That member functions may modify the object is, essentially, an exception to the rule. –  Lightness Races in Orbit Jun 24 '11 at 10:23
    
@David: And the cast is only for .str(), because op+ returns ostream. It's a bit of a red herring here as it has nothing to do with the question specifically. –  Lightness Races in Orbit Jun 24 '11 at 10:23

2 Answers 2

up vote 18 down vote accepted

I'm told that, in C++03, temporaries are implicitly non-modifiable.

That is not correct. Temporaries are created, among other circumstances, by evaluating rvalues, and there are both non-const rvalues and const rvalues. The value category of an expression and the constness of the object it denotes are mostly orthogonal 1. Observe:

      std::string foo();
const std::string bar();

Given the above function declarations, the expression foo() is a non-const rvalue whose evaluation creates a non-const temporary, and bar() is a const rvalue that creates a const temporary.

Note that you can call any member function on a non-const rvalue, allowing you to modify the object:

foo().append(" was created by foo")   // okay, modifying a non-const temporary
bar().append(" was created by bar")   // error, modifying a const temporary

Since operator= is a member function, you can even assign to non-const rvalues:

std::string("hello") = "world";

This should be enough evidence to convince you that temporaries are not implicitly const.

1: An exception are scalar rvalues such as 42. They are always non-const.

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See my answer. They're not const per-se, but they are also non-modifiable in all but some specified cases. Those specified cases include member function calls which probably covers the majority of use cases, but still. :) –  Lightness Races in Orbit Jun 24 '11 at 10:11
    
So std::string() is not an rvalue and thus a non-const variable? –  StackedCrooked Jun 24 '11 at 10:11
    
@StackedCrooked: It's an rvalue; it's not const, but it's also not modifiable (except under certain conditions, like calling a member function on it). –  Lightness Races in Orbit Jun 24 '11 at 10:12
    
@Stacked: std::string() is an rvalue that denotes a non-const temporary. It is not a variable, since variables always have names in C++. –  FredOverflow Jun 24 '11 at 10:25
    
@StackedCrooked: A different point of view that helps me think on that: you cannot bind a non-const reference to std::string(), but you can call any member method directly on it. Another different point of view is that the language has a clause (somewhere, you can search for it) that basically says that all lvalues are objects, and that some rvalues (rvalues of class types, for example) can also be objects. You can call a method on any object. –  David Rodríguez - dribeas Jun 24 '11 at 10:26

First, there's a difference between "modifying a temporary" and "modifying an object through an rvalue". I'll consider the latter, since the former is not really useful to discuss [1].

I found the following at 3.10/10 (3.10/5 in C++11):

An lvalue for an object is necessary in order to modify the object except that an rvalue of class type can also be used to modify its referent under certain circumstances. [Example: a member function called for an object (9.3) can modify the object. ]

So, rvalues are not const per-se but they are non-modifiable under all but some certain circumstances.

However, that a member function call can modify an rvalue would seem to indicate to me that the vast majority of cases for modifying an object through an rvalue are satisfied.

In particular, the assertion (in the original question I linked to) that (obj1+obj2).show() is not valid for non-const show() [ugh, why?!] was false.

So, the answer is (changing the question wording slightly for the conclusion) that rvalues, as accessed through member functions, are not inherently non-modifiable.


[1] - Notably, if you can obtain an lvalue to the temporary from the original rvalue, you can do whatever you like with it:

#include <cstring>

struct standard_layout {
    standard_layout();
    int i;
};

standard_layout* global;

standard_layout::standard_layout()
{
    global = this;
}

void modifying_an_object_through_lvalue(standard_layout&&)
{
    // Modifying through an *lvalue* here!
    std::memset(global, 0, sizeof(standard_layout));
}

int main()
{
    // we pass a temporary, but we only modify it through
    // an lvalue, which is fine
    modifying_an_object_through_lvalue(standard_layout{});
}

(Thanks to Luc Danton for the code!)

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1  
+1, and as an additional note, the usual semantics for a show() method (as per the original question), would be those of a constant method (show() does not seem to entail modify but rather only read), so even if temporaries were const, if the method is also const it should work. –  David Rodríguez - dribeas Jun 24 '11 at 10:23
    
@David: Indeed; I hadn't even noticed how poor the example is, since show() ought to be const anyway. :) I've edited to expand on that slightly. –  Lightness Races in Orbit Jun 24 '11 at 10:25
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BTW: Another approach to the same problem is considering that you can call member methods on objects, and 3.10/2 states that An lvalue refers to an object or function. Some rvalue expressions—those of class or cv-qualified class type— also refer to objects. Then the implication is that you can call methods for lvalues and rvalues of class or cv-qualified class type. –  David Rodríguez - dribeas Jun 24 '11 at 10:29
    
@David: You still need to come back to 3.10/10 to make sense of that, since "An lvalue for an object is necessary in order to modify the object, except [..]". –  Lightness Races in Orbit Jun 24 '11 at 10:33
    
If you aggregate the two rules into one, you will note that the meaning is that An object is required in order to be modified. That is, in both cases there is a common denominator lvalue or class type rvalue, that is the requisite for mutability in 3.10/10, or the definition of object in 3.10/2, which is what I failed to show in the last comment. –  David Rodríguez - dribeas Jun 24 '11 at 10:41

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