I was answering a question and recommending return by-value for a large type because I was confident the compiler would perform return-value optimization (RVO). But then it was pointed out to me that Visual Studio 2013 was not performing RVO on my code.

I've found a question here regarding Visual Studio failing to perform RVO but in that case the conclusion seemed to be that if it really matters Visual Studio will perform RVO. In my case it does matter, it makes a significant impact to performance which I've confirmed with profiling results. Here is the simplified code:

#include <vector>
#include <numeric>
#include <iostream>

struct Foo {
  std::vector<double> v;
  Foo(std::vector<double> _v) : v(std::move(_v)) {}
};

Foo getBigFoo() {
  std::vector<double> v(1000000);
  std::iota(v.begin(), v.end(), 0);  // Fill vector with non-trivial data

  return Foo(std::move(v));  // Expecting RVO to happen here.
}

int main() {
  std::cout << "Press any key to start test...";
  std::cin.ignore();

  for (int i = 0; i != 100; ++i) {  // Repeat test to get meaningful profiler results
    auto foo = getBigFoo();
    std::cout << std::accumulate(foo.v.begin(), foo.v.end(), 0.0) << "\n";
  }
}

I'm expecting the compiler to perform RVO on the return type from getBigFoo(). But it appears to be copying Foo instead.

I'm aware that the compiler will create a copy-constructor for Foo. I'm also aware that unlike a compliant C++11 compiler Visual Studio does not create a move-constructor for Foo. But that should be OK, RVO is a C++98 concept and works without move-semantics.

So, the question is, is there a good reason why Visual Studio 2013 does not perform return value optimization in this case?

I know of a few workarounds. I can define a move-constructor for Foo:

Foo(Foo&& in) : v(std::move(in.v)) {}

which is fine, but there are a lot of legacy types out there that don't have move-constructors and it would be nice to know I can rely on RVO with those types. Also, some types may be inherently copyable but not movable.

If I change from RVO to NVRO (named return value optimization) then Visual Studio does appear to perform the optimization:

  Foo foo(std::move(v))
  return foo;

which is curious because I thought NVRO was less reliable than RVO.

Even more curious is if I change the constructor of Foo so it creates and fills the vector:

  Foo(size_t num) : v(num) {
    std::iota(v.begin(), v.end(), 0);  // Fill vector with non-trivial data
  }

instead of moving it in then when I try to do RVO, it works:

Foo getBigFoo() {
  return Foo(1000000);
}

I'm happy to go with one of these workarounds but I'd like to be able to predict when RVO might fail like this in the future, thanks.

Edit: More concise live demo from @dyp

Edit2: Why don't I just write return v;?

For a start, it doesn't help. Profiler results show that Visual Studio 2013 still copies the vector if I just write return v; And even if it did work it would only be a workaround. I'm not trying to actually fix this particular piece of code, I'm trying to understand why RVO fails so I can predict when it might fail in the future. It is true that it is a more concise way of writing this particular example but there are plenty of cases where I couldn't just write return v;, for example if Foo had additional constructor parameters.

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    Well you could, of course, use return {std::move(v)}; since that constructor is not explicit. This does not require any (N)RVO, it is specified not to create a temporary. – dyp Sep 21 '14 at 21:00
  • 2
  • 7
    Why don't you just write return v;? – Marc Glisse Sep 21 '14 at 21:18
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    I just tried it on Visual Studio 2014 CTP and it applies RVO for your code. EDIT: @dyp's example I should say. – Jagannath Sep 21 '14 at 23:59
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    I've posted some details on when RVO is performed and when it fails (based on example from @dyp) here: rovrov.com/blog/2014/11/21/RVO-and-copy-elision-failing. This does not explain why RVO is failing but some observations might still be interesting. – Roman L Nov 21 '14 at 22:37

If the code looks like it should be optimized, but is not getting optimized I would submit bug here http://connect.microsoft.com/VisualStudio or raise a support case with Microsoft. This article, although it is for VC++2005 (I couldn't find a current version of document) does explain some scenarios where it won't work. http://msdn.microsoft.com/en-us/library/ms364057(v=vs.80).aspx#nrvo_cpp05_topic3

If we want to be sure the optimization has occurred, one possibility is to check the assembly output. This could be automated as a build task if desired.

This requires generating .asm output using /FAs option like so:

cl test.cpp /FAs

Will generate test.asm.

A potential example in PowerShell below, which can be used in this way:

PS C:\test> .\Get-RVO.ps1 C:\test\test.asm test.cpp
NOT RVO test.cpp - ; 13   :   return Foo(std::move(v));// Expecting RVO to happen here.

PS C:\test> .\Get-RVO.ps1 C:\test\test_v2.optimized.asm test.cpp
RVO OK test.cpp - ; 13   :   return {std::move(v)}; // Expecting RVO to happen here.

PS C:\test> 

The script:

# Usage Get-RVO.ps1 <input.asm file> <name of CPP file you want to check>
# Example .\Get-RVO.ps1 C:\test\test.asm test.cpp
[CmdletBinding()]
Param(
[Parameter(Mandatory=$True,Position=1)]
  [string]$assemblyFilename,

  [Parameter(Mandatory=$True,Position=2)]
  [string]$cppFilename
)

$sr=New-Object System.IO.StreamReader($assemblyFilename)
$IsInReturnSection=$false
$optimized=$true
$startLine=""
$inFile=$false

while (!$sr.EndOfStream)
{
    $line=$sr.ReadLine();

    # ignore any files that aren't our specified CPP file
    if ($line.StartsWith("; File"))
    {
        if ($line.EndsWith($cppFilename))
        {
            $inFile=$true
        }
        else
        {
            $inFile=$false
        }
    }

    # check if we are in code section for our CPP file...
    if ($inFile)
    {
        if ($line.StartsWith(";"))
        {
            # mark start of "return" code
            # assume optimized, unti proven otherwise
            if ($line.Contains("return"))
            {
                $startLine=$line 
                $IsInReturnSection=$true
                $optimized=$true
            }
        }

        if ($IsInReturnSection)
        {
            # call in return section, not RVO
            if ($line.Contains("call"))
            {
                $optimized=$false
            }

            # check if we reached end of return code section
            if ($line.StartsWith("$") -or $line.StartsWith("?"))
            {
                $IsInReturnSection=$false
                if ($optimized)
                {
                    "RVO OK $cppfileName - $startLine"
                }
                else
                {
                    "NOT RVO $cppfileName - $startLine"
                }
            }
        }
    }

}
  • I don't really want to have to check the assembly every time I want to use RVO! If this is necessary I think I will just not rely on RVO. I appreciate the instructions on how to generate/check the assembly though. I've confirmed Jagannath's observation that it is fixed in Visual Studio 2014 CTP so there is probably no point submitting a bug. – Chris Drew Nov 20 '14 at 3:00
  • This is the only possible way to be 100% sure, because even if you follow the logic as mentioned in Microsoft article I linked, a compiler bug may be there, or you hit a scenario that is not-obvious. However the script can be used to automate check post-build if it's very important. If you really want to know check the actual logic, I think you'd have to use an open source compiler CLang or GCC. – Malcolm McCaffery Nov 20 '14 at 3:30
  • That being said, if you have really well documented, reproducible scenario, Microsoft will typically respond to the bug report, it may be concluded "by design" but at least you may get a reason. – Malcolm McCaffery Nov 20 '14 at 3:31
  • @ChrisDrew "If this is necessary I think I will just not rely on RVO." -- Whenever possible, I strongly think that's exactly what you should do. There will always be programs where RVO is permitted by the standard but not performed by the compiler. It's practically impossible to guarantee that RVO is always performed whenever permitted, because when the to-be-returned object is constructed, the compiler may not be able to determine which return statement will end up executed. Optimise your move constructors, and RVO should have a significantly smaller impact. – user743382 Mar 29 '15 at 10:18
  • @ChrisDrew And unfortunately, that means spelling out each and every move constructor, if you're dealing with a compiler that won't generate them implicitly even though the standard says it should. – user743382 Mar 29 '15 at 10:20

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