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Imagine:

S f(S a) {
  return a;
}

Why is it not allowed to alias a and the return value slot?

S s = f(t);
S s = t; // can't generally transform it to this :(

The spec doesn't allow this transformation if the copy constructor of S has side effects. Instead, it requires at least two copies (one from t to a, and one from a to the return value, and another from the return value to s, and only that last one can be elided. Note that I wrote = t above to represent the fact of a copy of t to f's a, the only copy which would still be mandatory in the presence of side effects of move/copy constructor).

Why is that?

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1  
Because it isn't very useful to return the parameter unchanged? –  Bo Persson May 15 '11 at 15:39
3  
@BoP what if we change the parameter? S f(S s) { for(E &e : s) e.toupper(); return s; }. The compiler could do NRVO, and ignore the return s, because the return value is already in place. One copy/move less! –  Johannes Schaub - litb May 15 '11 at 15:42
1  
Hmm, maybe it has to do with calling conventions? The caller would have to know in what outgoing argument slot the return value is to be found. That's different for the other allowed forms of NRVO, it seems. I would like to get a nice answer explaining it :) –  Johannes Schaub - litb May 15 '11 at 15:54
2  
@Matthieu it doesn't matter whether or not the code is inlined. the copy has always to be done if it has side effects and NRVO cannot apply (observable side effects, that is). I would get one less copy if NRVO could apply in my case, I think. –  Johannes Schaub - litb May 15 '11 at 16:13
1  
@Bo, @Neil: surely the question isn't, "would this generally be a good/easy optimization?", the questions is, "why does the standard contain additional text, just to forbid this optimization?". There must have been a positive reason to forbid it, "it's not worth making" only explains the situation if it's just a matter of the standard omitting to allow it. –  Steve Jessop May 15 '11 at 16:44

6 Answers 6

Here's why copy elision doesn't make sense for parameters. It's really about the implementation of the concept at the compiler level.

Copy elision works by essentially constructing the return value in-place. The value isn't copied out; it's created directly in its intended destination. It's the caller who provides the space for the intended output, and thus it's ultimately the caller who provides the possibility for the elision.

All that the function internally needs to do in order to elide the copy is construct the output in the place provided by the caller. If the function can do this, you get copy elision. If the function can't, then it will use one or more temporary variables to store the intermediate results, then copy/move this into the place provided by the caller. It's still constructed in-place, but the construction of the output happens via copy.

So the world outside of a particular function doesn't have to know or care about whether a function does elision. Specifically, the caller of the function doesn't have to know about how the function is implemented. It's not doing anything different; it's the function itself that decides if elision is possible.

Storage for value parameters is also provided by the caller. When you call f(t), it is the caller that creates the copy of t and passes it to f. Similarly, if S is implicitly constructable from an int, then f(5) will construct an S from the 5 and pass it to f.

This is all done by the caller. The callee doesn't know or care that it was a variable or a temporary; it's just given a spot of stack memory (or registers or whatever).

Now remember: copy elision works because the function being called constructs the variable directly into the output location. So if you're trying to elide the return from a value parameter, then the storage for the value parameter must also be the output storage itself. But remember: it is the caller that provides that storage for both the parameter and the output. And therefore, to elide the output copy, the caller must construct the parameter directly into the output.

To do this, now the caller needs to know that the function it's calling will elide the return value, because it can only stick the parameter directly into the output if the parameter will be returned. That's not going to generally be possible at the compiler level, because the caller doesn't necessarily have the implementation of the function. If the function is inlined, then maybe it can work. But otherwise no.

Therefore, the C++ committee didn't bother to allow for the possibility.

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4  
Between C++03 and C++11, the committee changed "the expression is the name of a non-volatile automatic object" to "the expression is the name of a non-volatile automatic object (other than a function or catch-clause parameter)". So it is not the case that the committee "didn't bother to allow for the possibility". It was permitted in C++03 (perhaps accidentally), and then the committee went out of its way to ban it in C++11. –  Steve Jessop May 12 '12 at 18:08
    
What @SteveJessop said. I can't believe Nicol's answer has gotten so many upvotes; it's blatantly incorrect. –  Quuxplusone Dec 17 '13 at 9:50

The rationale, as I understand it, for that restriction is that the calling convention might (and will in many cases) demand that the argument to the function and the return object are at different locations (either memory or registers). Consider the following modified example:

X foo();
X bar( X a ) 
{ 
   return a;
}
int main() {
   X x = bar( foo() );
}

In theory the whole set of copies would be return statement in foo ($tmp1), argument a of bar, return statement of bar ($tmp2) and x in main. Compilers can elide two of the four objects by creating $tmp1 at the location of a and $tmp2 at the location of x. When the compiler is processing main it can note that the return value of foo is the argument to bar and can make them coincide, at that point it cannot possibly know (without inlining) that the argument and return of bar are the same object, and it has to comply with the calling convention, so it will place $tmp1 in the position of the argument to bar.

At the same time, it knows that the purpose of $tmp2 is only creating x, so it can place both at the same address. Inside bar, there is not much that can be done: the argument a is located in place of the first argument, according to the calling convention, and $tmp2 has to be located according to the calling convention, (in the general case in a different location, think that the example can be extended to a bar that takes more arguments, only one of which is used as return statement.

Now, if the compiler performs inlining it could detect that the extra copy that would be required if the function was not inlined is really not needed, and it would have a chance for eliding it. If the standard would allow for that particular copy to be elided, then the same code would have different behaviors depending on whether the function is inlined or not.

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1  
That's a reason not to do it sometimes in some situations, not a reason to flat out disallow it. The same code already has different behaviours depending on copy ellision. –  Puppy May 17 '11 at 10:45
    
@DeadMG: I don't quite follow the argument, if that was not disallowed, a compliant compiler would produce two different results for basically the same code based on actual inlining (not on the inline identifier being present, but real code inlining). –  David Rodríguez - dribeas May 17 '11 at 13:46
    
So all your reply boils down to need for expected side-effects in act of making additional unneeded copies? Basically we may lose oh-so-desired side effects of copy constructors and destructors of all these temporaries that are not called because of compiler optimized them out? For me a program whose correctness depends on such things is extremely hard to imagine as maintainable, robust or even readable. –  Öö Tiib May 28 '11 at 22:11
    
@Öö Tiib: I am not sure I follow your argument, whenever the compiler is able to optimize away a copy, what it does is remove the existence of one of the objects by having both be aliases of a single object, but in doing so the number of constructors/destructors executed is evened, that is, for each call to a constructor, a destructor is called. Each acquired resource is released. If the constructor/destructor has extra side effects (besides construction/destruction of the object) those may differ. Consider a class that counts the number of instances created, that value will differ. –  David Rodríguez - dribeas May 29 '11 at 22:59
1  
struct test { static int created; static int destroyed; test() { ++created; } test( test const & ) { ++created; } ~test() { ++destroyed; } }; int test::created = 0; int test::destroyed = 0; The final numbers for test::created and test::destroyed may differ, but that is something that has been so for a very long time already. The current standard does allow for copy elision, which would have that exact same problems. That is, programmers must know where and when copies might be elided, and understand what that means and how that can affect the semantics of your program. –  David Rodríguez - dribeas May 29 '11 at 23:05

From t to a it is unreasonable to elide copy. The parameter is declared mutable, so copying is done because it is expected to be modified in function.

From a to return value i can not see any reasons to copy. Perhaps it is some sort of oversight? The by-value parameters feel like locals inside function body ... i see no difference there.

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Not an oversight, I think. C++03 doesn't make a special case of function parameters (so I think the elision is allowed in C++03, perhaps unintentionally). The C++0x FDIS adds "other than a function or catch-clause parameter") to the text permitting NRVO. –  Steve Jessop May 15 '11 at 17:02
    
Then i see no other reason but some members of committee whose legacy libraries pass by const reference and then copy. So they decided to encourage that pattern. –  Öö Tiib May 15 '11 at 17:13
    
For everyone interested: I asked in the #llvm channel, and they said that it's probably noone thought of that optimization. I wonder how clang/gcc cope on delete/new calls in copy ctors of typical C++03 classes though. Whether they can optimize the copy away knowing they aren't observable side effects. Otherwise, having the spec not forbid it would be nice, if there aren't any problems, I think! –  Johannes Schaub - litb May 15 '11 at 20:04
    
@JohannesSchaub-litb It's not true that "noone thought of that optimization". Someone in the Danish national body did notice that the optimization was permitted, and went out of their way to disallow in C++11 what had previously been allowed in C++03. (source: open-std.org/jtc1/sc22/wg21/docs/cwg_defects.html#1148 ) So we need a better answer than that. There must be some reason that the Danish body believed this optimization was too dangerous to permit. (Tinfoil hat time, but Öö Tiib might be on to something with his suggestion above...) –  Quuxplusone Dec 17 '13 at 10:02

David Rodríguez - dribeas answer to my question 'How to allow copy elision construction for C++ classes' gave me the following idea. The trick is to use lambdas to delay evaluation til inside the function body:

#include <iostream>

struct S
{
  S() {}
  S(const S&) { std::cout << "Copy" << std::endl; }
  S(S&&) { std::cout << "Move" << std::endl; }
};

S f1(S a) {
  return a;
}

S f2(const S& a) {
  return a;
}

#define DELAY(x) [&]{ return x; }

template <class F>
S f3(const F& a) {
  return a();
}

int main()
{
  S t;
  std::cout << "Without delay:" << std::endl;
  S s1 = f1(t);
  std::cout << "With delay:" << std::endl;
  S s2 = f3(DELAY(t));
  std::cout << "Without delay pass by ref:" << std::endl;
  S s3 = f2(t);
  std::cout << "Without delay pass by ref (temporary) (should have 0 copies, will get 1):" << std::endl;
  S s4 = f2(S());
  std::cout << "With delay (temporary) (no copies, best):" << std::endl;
  S s5 = f3(DELAY(S()));
}

This outputs on ideone GCC 4.5.1:

Without delay:
Copy
Copy
With delay:
Copy

Now this is good, but one could suggest that the DELAY version is just like passing by const reference, as below:

Without delay pass by ref:
Copy

But if we pass a temporary by const reference, we still get a copy:

Without delay pass by ref (temporary) (should have 0 copies, will get 1):
Copy

Where the delayed version elides the copy:

With delay (temporary) (no copies, best):

As you can see, this elides all copies in the temporary case.

The delayed version produces one copy in the non-temporary case, and no copies in the case of a temporary. I don't know any way to achieve this other than lambdas, but I'd be interested if there is.

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I think the issue is that if the copy constructor does something, then the compiler must do that thing a predictable number of times. If you have a class that increments a counter every time it's copied, for example, and there's a way to access that counter, then a standards-compliant compiler must do that operation a well-defined number of times (otherwise, how would one write unit tests?)

Now, it's probably a bad idea to actually write a class like that, but it's not the compiler's job to figure that out, only to make sure that the output is correct and consistent.

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1  
Copy elision is specifically allowed in certain circumstances, regardless of whether the copy constructor has side effects. –  ildjarn Mar 5 '12 at 22:40
    
Ok, that's true. But I think those are circumstances where the sequence of events is not guaranteed anyway. –  bdow Mar 5 '12 at 22:51
1  
My point is, your rationale makes no sense because there are already legal circumstances where the copy constructor will be skipped. –  ildjarn Mar 5 '12 at 22:53

I feel, because the alternative is always available for the optimization:

S& f(S& a) { return a; }  // pass & return by reference
^^^  ^^^

If f() is coded as mentioned in your example, then it's perfectly alright to assume that copy is intended or side effects are expected; otherwise why not to choose the pass/return by reference ?

Suppose if NRVO applies (as you ask) then there is no difference between S f(S) and S& f(S&)!

NRVO kicks in the situations like operator +() (example) because there is no worthy alternative.

One supporting aspect, all below function have different behaviors for copying:

S& f(S& a) { return a; }  // 0 copy
S f(S& a) { return a; } // 1 copy
S f(S a) { A a1; return (...)? a : a1; }  // 2 copies

In the 3rd snippet, if the (...) is known at compile time to be false then compiler generates only 1 copy.
This means, that compiler purposefully doesn't perform optimization when a trivial alternative is available.

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Except that the reference form cannot work with temporaries –  Martin Ba Nov 15 '12 at 9:28
    
@MartinBa, const S& f(const S& a); will work for temporaries as well. –  iammilind Nov 15 '12 at 11:24
    
Yeah, the const& version will OC work for temps as well, but that's not what you present in your answer. (And the arg be const seems really useless) –  Martin Ba Nov 15 '12 at 20:10
    
@MartinBa, that's what my argument. We don't need another optimization as asked by OP. There are several alternatives already available, some are useful some are useless. –  iammilind Nov 16 '12 at 4:20
    
@iammilind's proposed workaround is ridiculously inefficient in the case where S is a template type parameter with the type int. One of the great advantages of C++ is that we usually don't have to write different code for primitive types versus user-defined types; let's not throw that advantage away if we don't have to. Besides, the question wasn't "how do I work around this issue", it was "why does this issue exist in the first place". –  Quuxplusone Dec 17 '13 at 9:54

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