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You have two arrays and a function that counts differences between them:

for( i = 0; i < len; ++i ) { 
    int value1 = vector1[i];
    int value2 = vector2[i];
    if( value1 != value2 ) ++num_differences;
}

As branching downgrades performance, it can be optimized to:

for( i = 0; i < len; ++i ) {
    num_differences += !!(vector1[i] != vector2[i])
}
// !!(..) is to be sure that the result is boolean 0 or 1

so there is no if clause. But does it practically make sense? With GCC (and other compilers) being so smart, does it make sense to play with such optimizations?

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4  
why do you need !!, with a !=? triple negative. mind blown. –  K Mehta Mar 5 '12 at 8:16
    
Have you tried measuring it? Current x86-64 processors have conditional move instructions, so no branching is needed in your first example. (assuming the compiler is smart enough to generate them) –  Mysticial Mar 5 '12 at 8:18
1  
@KshitijMehta is right. The result of the != is guaranteed to be 0 or 1. –  Jens Gustedt Mar 5 '12 at 8:35

4 Answers 4

Unless len is several millions large or you're comparing a lot of arrays, then no. The second version is less readable (not so much to an experienced programmer), so I'd prefer the first variant, unless this is the bottleneck (doubtful).

The following codes are generated, with optimizations:

   for( i = 0; i < 4; ++i ) { 
    int value1 = vector1[i];
    int value2 = vector2[i];
    if( value1 != value2 ) ++num_differences;
00401000  mov         ecx,dword ptr [vector1 (40301Ch)] 
00401006  xor         eax,eax 
00401008  cmp         ecx,dword ptr [vector2 (40302Ch)] 
0040100E  je          wmain+15h (401015h) 
00401010  mov         eax,1 
00401015  mov         edx,dword ptr [vector1+4 (403020h)] 
0040101B  cmp         edx,dword ptr [vector2+4 (403030h)] 
00401021  je          wmain+26h (401026h) 
00401023  add         eax,1 
00401026  mov         ecx,dword ptr [vector1+8 (403024h)] 
0040102C  cmp         ecx,dword ptr [vector2+8 (403034h)] 
00401032  je          wmain+37h (401037h) 
00401034  add         eax,1 
00401037  mov         edx,dword ptr [vector1+0Ch (403028h)] 
0040103D  cmp         edx,dword ptr [vector2+0Ch (403038h)] 
00401043  je          wmain+48h (401048h) 
00401045  add         eax,1 
   }

   for( i = 0; i < 4; ++i ) {
    num_differences += !!(vector1[i] != vector2[i]);
00401064  mov         edx,dword ptr [vector1+0Ch (403028h)] 
0040106A  xor         eax,eax 
0040106C  cmp         edx,dword ptr [vector2+0Ch (403038h)] 
00401072  mov         edx,dword ptr [vector1+8 (403024h)] 
00401078  setne       al   
0040107B  xor         ecx,ecx 
0040107D  cmp         edx,dword ptr [vector2+8 (403034h)] 
00401083  mov         edx,dword ptr [vector1+4 (403020h)] 
00401089  setne       cl   
0040108C  add         eax,ecx 
0040108E  xor         ecx,ecx 
00401090  cmp         edx,dword ptr [vector2+4 (403030h)] 
00401096  mov         edx,dword ptr [vector1 (40301Ch)] 
0040109C  setne       cl   
0040109F  add         eax,ecx 
004010A1  xor         ecx,ecx 
004010A3  cmp         edx,dword ptr [vector2 (40302Ch)] 
004010A9  setne       cl   
004010AC  add         eax,ecx 
   }

So, actually, the second version is slightly slower (theoretically). 19 instructions for the second vs. 17 for the first.

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2  
There's more to it than just counting instructions. The first one has branching and the second doesn't. If anything, I'd guess that the first version is actually slower. –  Mysticial Mar 5 '12 at 8:25
1  
@Mysticial I know, there's also micro-instructions to be aware of. But I think it's good enough for a very rough estimate. But you're the performance expert, why don't you give a thorough answer? :) –  Luchian Grigore Mar 5 '12 at 8:27
    
Meh... Too lazy to knock up a benchmark. It's 2:30 AM here - should probably get some sleep. –  Mysticial Mar 5 '12 at 8:29
    
@Mysticial is probably right, though it depends a lot on the data. Random data would (strangely) yield an excellent prediction rate (the values would almost never be equal), so the branch version would be fast. But for random 0/1 values, prediction rate would be poor, and branches will cost much more. And all that, assuming the compiler indeed implements if as a branch. –  ugoren Mar 5 '12 at 12:32

You should compare the code the compiler generates. It may be equivalent.

The compiler's very smart, but a good engineer can certainly improve a program's performance.

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The short answer is: "Trust your Compiler".

In general you're not going to see much benefit from optimisations like this unless you're working with really huge datasets. Even then you really need to benchmark the code to see if there is any improvement.

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Hooray for letting the machines do micro-optimization so you can spend your time finding a better way to solve the larger problem –  tbert Mar 5 '12 at 8:22
    
Most of times there won't be any difference at all on final binary. Machine optimizes, that's the way it is and that's the way it should be –  ArcDare Mar 5 '12 at 15:29
    
The compiler is only as good as the source code you feed it. Learn how to help the compiler do a better job and you will automatically become a better programmer. –  Olof Forshell Mar 6 '12 at 9:01
    
@tbert: the problem is that most programmers solve the larger problem and then leave it. The "better way" doesn't come into play, more likely the "first way." –  Olof Forshell Mar 6 '12 at 9:03
    
@ArcDare: "won't be any difference at all" are you saying that on the basis of your own failed attempts or just passing on something you've heard? My personal experience is exactly the opposite. –  Olof Forshell Mar 6 '12 at 9:06

I dont think you are going to do much better, your second example is hard to read/understand for the average programmer which means two things one hard to understand and maintain, two you may be creeping into dark, less tested/supported, corners of the compiler. Drive down the road between the lines, dont wander about on the shoulder or in the wrong lane.

Go with this

for( i = 0; i < len; ++i ) { 
    int value1 = vector1[i];
    int value2 = vector2[i];
    if( value1 != value2 ) ++num_differences;
}

or this

for( i = 0; i < len; ++i ) { 
    if( vector1[i] != vector2[i] ) ++num_differences;
}

if it really is bothering you and you have properly concluded this is your performance bottleneck then time the difference between them. From the disassembly shown, and the nature of this platform, it is very difficult to properly time such things and draw the right conclusions. Too many caches, and other factors that cloud over the results, leading to false conclusions, etc. and no two x86 implementations have the same performance so if you happen to tune for your computer you are likely detuning it for another model of x86 or even the same make on a different motherboard with different I/O characteristics.

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I guess we are all assuming this is x86, is it x86? –  dwelch Mar 5 '12 at 15:20

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