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Are C++ compilers able to apply RVO for virtual functions?

In this case:

class AbstractReader
{
//...
public:
    virtual std::vector<float> getFloatVector() = 0;
//...
}

class XmlReader : public AbstractReader
{
//...
public:
    virtual std::vector<float> getFloatVector()
    {
        std::vector<float> result;

        //Do some parsing here...

        return result;
    }
//...
}



class BinaryReader : public AbstractReader
{
//...
public:
    virtual std::vector<float> getFloatVector()
    {
        std::vector<float> result;

        //Do some decoding here...

        return result;
    }
//...
}

Can RVO apply to return result; lines? I would guess not.

Then, is std::move(result) the way to go for returning large containers in that case?

Thanks

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10
  • 1
    Can you please clarify your question? Do you often return virtual functions?
    – juanchopanza
    Oct 9, 2014 at 13:24
  • 1
    @juanchopanza: I think the question is whether RVO works within a virtual function, i.e. for anything the virtual function might return, not whether RVO works when returning a virtual function. (And I don't see a reason why that shouldn't in principle work)
    – Damon
    Oct 9, 2014 at 13:28
  • @Damon I think the same, but better let OP explain what they actually mean to ask.
    – juanchopanza
    Oct 9, 2014 at 13:31
  • The virtual mechanism is just there to select which function gets called. After that selection I would think whatever actual function is selected will have RVO compiled into it if appropriate. I don't see that the compiler needs to know what the other functions do when dealing with each specific function.
    – Galik
    Oct 9, 2014 at 13:41
  • I do not know how RVO works, but I would have guessed that the linker must know if RVO occurs or not. Is the RVO mechanism totally transparent to the caller?
    – galinette
    Oct 9, 2014 at 13:50

2 Answers 2

Reset to default
5

Yes, the compiler can perform RVO. I cooked up some testing code and ran it through godbolt:

struct M {
  M();
  M(const M&);
  M(M &&);
  ~M();
  double * ptr;
};

M getM();

struct A {
  virtual M foo() = 0;
};

struct B : A {
  virtual M foo() override;
};

M B::foo(){
  M m;
  return m;
}

struct C : B {
  virtual M foo() override;
};
M C::foo(){
  M m = getM();
  return m;
}

A* getA();

int main(){
  A* p = getA();
  M m = p->foo();
}

g++ -O3 produces

B::foo():
    pushq   %rbx
    movq    %rdi, %rbx
    call    M::M()
    movq    %rbx, %rax
    popq    %rbx
    ret
C::foo():
    pushq   %rbx
    movq    %rdi, %rbx
    call    getM()
    movq    %rbx, %rax
    popq    %rbx
    ret
main:
    subq    $24, %rsp
    call    getA()
    movq    (%rax), %rdx
    movq    %rax, %rsi
    movq    %rsp, %rdi
    call    *(%rdx)
    movq    %rsp, %rdi
    call    M::~M()
    xorl    %eax, %eax
    addq    $24, %rsp
    ret

Conspicuously absent from the disassembly is any call to the copy or move constructor of M.

Also, the paragraph of the standard setting out the criteria for copy elision draws no distinction between virtual and nonvirtual member functions, and whenever the standard for copy elision is met, overload resolution for the return statement "is first performed as if the object were designated by an rvalue".

That is to say, in a function

M foo() {
    M m = /*...*/;
    return m;
}

If copy elision can't take place for whatever reason, and a move constructor is available, return m; will always invoke the move constructor rather than the copy constructor. Hence, there's no need to use std::move for the return statement if you are returning a local variable.

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1

If you return std::move(result);, you cannot gain anything, and you can lose. So don't do it.

You cannot gain anything, because the standard explicitly says "if RVO conditions are met, or you're returning a parameter, try returning as rvalue first and only if that wouldn't compile, return as lvalue. So even if you return result;, the compiler is forced to try return std::move(result); first.

You can lose, since return std::move(result); specifically prevents RVO if it was otherwise applicable.

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4
  • Actually, in cases RVO is not possible, and if the returned type is movable and has a large underlying buffer, you can gain a lot. This is also not an answer to the question.
    – galinette
    Oct 9, 2014 at 13:48
  • 2
    @galinette No, if copy elision can't be performed for whatever reason, return result; will still perform a move when possible.
    – T.C.
    Oct 9, 2014 at 13:50
  • @galinette Well, if RVO is not possible, then result is neither a local variable nor a parameter of the function, so using std::move is not a no-brainer in this case anyway. You were asking about RVO, so I assumed a situation where RVO criteria are met.
    – Angew is no longer proud of SO
    Oct 9, 2014 at 13:53
  • @galinette Regarding the example you've added to the question, even if RVO doesn't happen (it's always optional), the criteria for RVO are met, and therefore the compiler must try the rvalue overloads first.
    – Angew is no longer proud of SO
    Oct 9, 2014 at 13:56

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