6

This code example will output time: 0 regardless of the value of N when compiled with Visual Studio Professional 2013 Update 3 in release mode, both 32 and 64-bit option:

#include <iostream>
#include <functional>
#include <ctime>

using namespace std;

void bar(int i, int& x, int& y)  {x = i%13; y = i%23;}

int g(int N = 1E9) {   
  int x, y;
  int r = 0;

  for (int i = 1; i <= N; ++i) {
    bar(i, x, y);
    r += x+y;
  }

  return r;
}

int main()
{
    auto t0 = clock();
    auto r  = g();
    auto t1 = clock();

    cout << r << "  time: " << t1-t0 << endl;

    return 0;
}

When tested with gcc, clang and other version of vc++ on rextester.com, it behaves correctly and outputs time greater than zero. Any clues what is going on here?

I noticed that inlining the g() function restores correct behaviour, but changing declaration and initialization order of t0, r and t1 does not.

  • 3
    Likely the time to do the operation is below the resolution of the timer Windows is using when calling clock(). I recently wrote an answer here that may give you an idea of using Higher Resolution timers on Windows: stackoverflow.com/questions/25954602/ctimespan-always-gets-zero – Michael Petch Oct 4 '14 at 3:03
  • 2
    It is an optimization issue (compiler thinks that calling g has no side effects) so it actually puts both calls to clock before your call to g. You should be able to resolve this by changing auto r = g(); to volatile auto r = g(); – Michael Petch Oct 4 '14 at 3:41
  • 1
    @MichaelPetch your volatile will prevent g from moving after the second clock, but you also need something to prevent it from moving before the first clock, for instance: volatile n=42; volatile auto r=g(n);. – Marc Glisse Oct 4 '14 at 17:26
  • 1
    @Paul No, sorry. Think of g() as something computing 2+2. It could be computed at compile-time, or at the beginning of main, or between the 2 clock, all you know is that it has been computed before being stored in r. To clarify things, a statement like volatile auto r = g(); doesn't have to stay in one piece. The compiler first splits it into auto tmp=g(); volatile auto r=tmp; and the first part can move as early as it likes, since it has no side effect and does not depend on anything. – Marc Glisse Oct 4 '14 at 19:58
  • 1
    @Paul right. Note that this line defining n can be before or after the first clock, it doesn't matter. Reading the value of n is a side effect, so it cannot commute with clock. And since g depends on that value, g must remain after that read. – Marc Glisse Oct 5 '14 at 7:17
9

If you look at the disassembly winddow using the debugger you can see the generated code. For VS2012 express in release mode you get this:

00AF1310  push        edi  
    auto t0 = clock();
00AF1311  call        dword ptr ds:[0AF30E0h]  
00AF1317  mov         edi,eax  
    auto r  = g();
    auto t1 = clock();
00AF1319  call        dword ptr ds:[0AF30E0h]  

    cout << r << "  time: " << t1-t0 << endl;
00AF131F  push        dword ptr ds:[0AF3040h]  
00AF1325  sub         eax,edi  
00AF1327  push        eax  
00AF1328  call        g (0AF1270h)  
00AF132D  mov         ecx,dword ptr ds:[0AF3058h]  
00AF1333  push        eax  
00AF1334  call        dword ptr ds:[0AF3030h]  
00AF133A  mov         ecx,eax  
00AF133C  call        std::operator<<<std::char_traits<char> > (0AF17F0h)  
00AF1341  mov         ecx,eax  
00AF1343  call        dword ptr ds:[0AF302Ch]  
00AF1349  mov         ecx,eax  
00AF134B  call        dword ptr ds:[0AF3034h]  

from the first 4 lines of assembly you can see that the two calls to clock (ds:[0AF30E0h]) happen before the call to g. So in this case it doesn't matter how long g takes, the result will only show the time take between those two sequential calls.

It seems VS has determined that g doesn't have any side effects that would affect clock so it is safe to move the calls around.

As Michael Petch points out in the comments, adding volatile to to the declaration of r will stop the compiler from moving the call.

  • 1
    Marking r as volatile would probably be enough for the compiler to change that behavior. I'd expect this would work volatile auto r = g(); – Michael Petch Oct 4 '14 at 3:36
  • Is it legal? Following this reasoning, almost all computations don't affect clock so it could be moved anywhere by compiler, but it would be a sheer madness. – Paul Jurczak Oct 4 '14 at 3:43
  • @MichaelPetch you are correct - that does it - I'll add it in the answer. – The Dark Oct 4 '14 at 3:43
  • 1
    @MichaelPetch there is a reasonable expectation that what the user observes would be the same with or without optimizations - in fact, there is such a requirement. I just looked up The C++ Programming Language, 4th Edition and on page 225 it reads: A compiler may reorder code to improve performance as long as the result is identical to that of the simple order of execution – Paul Jurczak Oct 4 '14 at 4:02
  • 1
    Yes, it would be reasonable to call what you experienced an optimization bug. Volatile keyword exists to give hints to the compiler that such optimizations on variables (values, pointers etc) shouldn't occur. Using optimization comes with these kind of pitfalls. It is usually why most compilers allow you to turn off certain optimizations or set different levels. – Michael Petch Oct 4 '14 at 4:08

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