The following critical loop of a piece of numerical software, written in C++, basically compares two objects by one of their members:

for(int j=n;--j>0;)

a and b are of class ASD:

struct ASD  {
    float e;

I was investigating the effect of putting this comparison in a lightweight member function:

bool test(const ASD& y)const {
    return e<y.e;

and using it like this:

for(int j=n;--j>0;)

The compiler is inlining this function, but the problem is, that the assembly code will be different and cause >10% of runtime overhead. I have to question:


  1. Why is the compiler prodrucing different assembly code?

  2. Why is the produced assembly slower?

EDIT: The second question has been answered by implementing @KamyarSouri's suggestion (j%16). The assembly code now looks almost identical (see http://pastebin.com/diff.php?i=yqXedtPm). The only differences are the lines 18, 33, 48:

000646F9  movzx       edx,dl 


This chart shows the FLOP/s (up to a scaling factor) for 50 testruns of my code.

enter image description here

The gnuplot script to generate the plot: http://pastebin.com/8amNqya7

Compiler Options:

/Zi /W3 /WX- /MP /Ox /Ob2 /Oi /Ot /Oy /GL /D "WIN32" /D "NDEBUG" /D "_CONSOLE" /D "_UNICODE" /D "UNICODE" /Gm- /EHsc /MT /GS- /Gy /arch:SSE2 /fp:precise /Zc:wchar_t /Zc:forScope /Gd /analyze-

Linker Options: /INCREMENTAL:NO "kernel32.lib" "user32.lib" "gdi32.lib" "winspool.lib" "comdlg32.lib" "advapi32.lib" "shell32.lib" "ole32.lib" "oleaut32.lib" "uuid.lib" "odbc32.lib" "odbccp32.lib" /ALLOWISOLATION /MANIFESTUAC:"level='asInvoker' uiAccess='false'" /SUBSYSTEM:CONSOLE /OPT:REF /OPT:ICF /LTCG /TLBID:1 /DYNAMICBASE /NXCOMPAT /MACHINE:X86 /ERRORREPORT:QUEUE

  • Nice question. It might be instructive to post the optimization and other relevant compiler settings used to produce this result.
    – Ted Hopp
    Commented Dec 21, 2011 at 1:08
  • 10
    Oh man... Somebody seems to have learned the art of asking stellar questions... Only this time, I don't have the answer off the top of my head...
    – Mysticial
    Commented Dec 21, 2011 at 1:18
  • 1
    @Johannes Gerer: j%10 can take quite some time compared to the a.e<b.e. Can you try re doing the test by replacing j%10 with something like j%16 which will be replaced by &15 ? Commented Dec 21, 2011 at 1:24
  • 1
    Well, in this case it's apparently a M$ compiler, so that may be a big chunk of the problems. But it may be, as someone else hinted, that the compiler at least partially thinks it's in debug mode, or otherwise has optimization "dialed down".
    – Hot Licks
    Commented Dec 21, 2011 at 2:02
  • 1
    Yeah, from Mystical's post it appears to be mostly "bad luck". There's a certain statistical nature to optimization -- the same optimization that "wins" 99% of the time can bite you 1% of the time. And being a little careless with that xor implementation usually wouldn't matter, but maybe does in this case (or the problem may be unrelated and due to slight cache boundary differences or some such. I've even seen cases where a program would run at different speeds when recompiled multiple times, just based on how it got mapped to memory.
    – Hot Licks
    Commented Dec 21, 2011 at 2:18

2 Answers 2


Short Answer:

Your asd array is declared as this:

int *asd=new int[16];

Therefore, use int as the return type rather than bool.
Alternatively, change the array type to bool.

In any case, make the return type of the test function match the type of the array.

Skip to bottom for more details.

Long Answer:

In the manually inlined version, the "core" of one iteration looks like this:

xor         eax,eax  
mov         edx,ecx  
and         edx,0Fh  
mov         dword ptr [ebp+edx*4],eax  
mov         eax,dword ptr [esp+1Ch]  
movss       xmm0,dword ptr [eax]  
movss       xmm1,dword ptr [edi]  
cvtps2pd    xmm0,xmm0  
cvtps2pd    xmm1,xmm1  
comisd      xmm1,xmm0  

The compiler inlined version is completely identical except for the first instruction.

Where instead of:

xor         eax,eax

it has:

xor         eax,eax  
movzx       edx,al

Okay, so it's one extra instruction. They both do the same - zeroing a register. This is the only difference that I see...

The movzx instruction has a single-cycle latency and 0.33 cycle reciprocal throughput on all the newer architectures. So I can't imagine how this could make a 10% difference.

In both cases, the result of the zeroing is used only 3 instructions later. So it's very possible that this could be on the critical path of execution.

While I'm not an Intel engineer, here's my guess:

Most modern processors deal with zeroing operations (such as xor eax,eax) via register renaming to a bank of zero registers. It completely bypasses the execution units. However, it's possible that this special handling could cause a pipeline bubble when the (partial) register is accessed via movzx edi,al.

Furthermore, there's also a false dependency on eax in the compiler inlined version:

movzx       edx,al  
mov         eax,ecx  //  False dependency on "eax".

Whether or not the out-of-order execution is able to resolve this is beyond me.

Okay, this is basically turning into a question of reverse-engineering the MSVC compiler...

Here I'll to explain why that extra movzx is generated as well as why it stays.

The key here is the bool return value. Apparently, bool datatypes are probably as stored 8-bit values inside the MSVC internal-representation. Therefore when you implicitly convert from bool to int here:

asd[j%16] = a.test(b);
^^^^^^^^^   ^^^^^^^^^
 type int   type bool

there is an 8-bit -> 32-bit integer promotion. This is the reason why MSVC generates the movzx instruction.

When the inlining is done manually, the compiler has enough information to optimize out this conversion and keeps everything as a 32-bit datatype IR.

However, when the code is put into it's own function with a bool return value, the compiler is not able to optimize out the 8-bit intermediate datatype. Therefore, the movzx stays.

When you make both datatypes the same (either int or bool), no conversion is needed. Hence the problem is avoided altogether.

  • Sorry, I just found the same instruction after updaten the program. Well, as you know the art of asking stellar answers, this should hurt your answer. Commented Dec 21, 2011 at 2:07
  • Actually, the same thing holds. Replacing the %10 with %16 only gets rid of the multiply and shift logic. The movzx is still there - only in compiler inlined version.
    – Mysticial
    Commented Dec 21, 2011 at 2:10
  • Come to think of it, I think your edit has strengthened my answer... It removes the noise of the %10 and adds a new reason for a stall.
    – Mysticial
    Commented Dec 21, 2011 at 2:17
  • You solved it! You might call this a higher form of return value optimization (which MSVC is missing here). Before I posted this strange code, the only cause I could imagine actually was the bool? -> int` conversion, but I immediately discarded this idea. Commented Dec 21, 2011 at 4:11
  • Yeah, that was another fun question to answer. Hacking into the compiler and assembly...
    – Mysticial
    Commented Dec 21, 2011 at 4:21

lea esp,[esp] occupies 7 bytes of i-cache and it's inside the loop. A few other clues make it look like the compiler isn't sure if this is a release build or a debug build.


The lea esp,[esp] isn't in the loop. The position among the surrounding instructions misled me. Now it looks like it intentionally wasted 7 bytes, followed by another wasted 2 bytes, in order to start the actual loop at a 16-byte boundary. Which means that this actually speeds things up, as observed by Johennes Gerer.

The compiler still seems to be uncertain whether this is a debug or release build though.

Another edit:

The pastebin diff is different from the pastebin diff that I saw earlier. This answer could be deleted now, but it already has comments so I'll leave it.

  • Yes, but the lea esp,[esp] is in the (faster) manually inlined version! Commented Dec 21, 2011 at 1:41
  • How could I insist on a "Release build"? You can find the compiler options I used in the OP Commented Dec 21, 2011 at 1:54

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