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In my code I must choose one of this two expressions (where mask and i non constant integer numbers -1 < i < (sizeof(int) << 3) + 1). I don't think that this will make preformance of my programm better or worse, but it is very interesting for me. Do you know which is better and why?

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4  
Why not try both and compare? (I am assuming the two expressions are equivalent for your use case) – NPE Mar 25 '11 at 17:31
1  
This looks very much like a homework/exam question to me. – Brian Driscoll Mar 25 '11 at 17:32
    
Can you clarify what "mask" and "i" are? – Seth Johnson Mar 25 '11 at 17:32
    
Those expressions don't do the same thing. So who cares if one is faster than the other? (mask >> i & 1) shifts mask right 0 or 1 bits. (mask & 1 << i) shifts the rightmost bit of mask to the left i times. You need to clarify what you want. – Adrian McCarthy Mar 25 '11 at 17:48
    
@Adrian the question not about what this expresions do :) this is just funny question. Take it easy. – Mihran Hovsepyan Mar 25 '11 at 17:54
up vote 3 down vote accepted

C expressions cannot be "faster" or "slower", because CPU cannot evaluate them directly.

Which one is "faster" depends on the machine code your compiler will be able to generate for these two expressions. If your compiler is smart enough to realize that in your context both do the same thing (e.g. you simply compare the result with zero), it will probably generate the same code for both variants, meaning that they will be equally fast. In such case it is quite possible that the generated machine code will not even remotely resemble the sequence of operations in the original expression (i.e. no shift and/or no bitwise-and). If what you are trying to do here is just test the value of one bit, then there are other ways to do it besides the shift-and-bitwise-and combination. And many of those "other ways" are not expressible in C. You can't use them in C, while the compiler can use them in machine code.

For example, the x86 CPU has a dedicated bit-test instruction BT that extracts the value of a specific bit by its number. So a smart compiler might simply generate something like

MOV eax, i
BT  mask, eax
...

for both of your expressions (assuming it is more efficient, of which I'm not sure).

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First of all, whenever you find yourself asking "which is faster", your first reaction should be to profile, measure and find out for yourself.

Second of all, this is such a tiny calculation, that it almost certainly has no bearing on the performance of your application.

Third, the two are most likely identical in performance.

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+1 Agree, but usually my thought processes work with the order of the first two paragraphs reversed. – R. Martinho Fernandes Mar 25 '11 at 17:35
    
1.Profiling this in different boxes with differnt OSes and getting some result I can't be sure that my result is correct one, but here can be a persons[s] who can answer to question more detailed. 2.I know that this wouldn't make performance of the application better or worse, this is just for interest. 3.It seems yes :) – Mihran Hovsepyan Mar 25 '11 at 17:43

Use either one and let your compiler optimize it however it likes.

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If "i" is a compile-time constant, then the second would execute fewer instructions -- the 1 << i would be computed at compile time. Otherwise I'd imagine they'd be the same.

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...on some architectures. – Stephen Canon Mar 25 '11 at 17:32
2  
"i" is imaginary unit. – ybungalobill Mar 25 '11 at 17:33

Depends entirely on where the values mask and i come from, and the architecture on which the program is running. There's also nothing to stop the compiler from transforming one into the other in situations where they are actually equivalent.

In short, not worth worrying about unless you have a trace showing that this is an appreciable fraction of total execution time.

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It is unlikely that either will be faster. If you are really curious, compile a simple program that does both, disassemble, and see what instructions are generated.

Here is how to do that:

gcc -O0 -g main.c -o main
objdump -d main | less
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It's easier to just use the -S flag in GCC. And since we're looking at "after the compiler has optimized at least a little", presumably, you should be using -O2 – Seth Johnson Mar 25 '11 at 17:33
    
@Seth Thanks, I forgot about -S. As for -O0 vs. -O2, it depends on what you're looking for. If you do -O2 and find that they are the same, you could do -O0 and see if the optimizer was doing extra work in one case or the other. – Jonathan Mar 25 '11 at 17:35

You could examine the assembly output and then look-up how many clock cycles each instruction takes.

But in 99.9999999 percent of programs, it won't make a lick of difference.

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The 2 expressions are not logically equivalent, performance is not your concern!

If performance was your concern, write a loop to do 10 million of each and measure.

EDIT: You edited the question after my response ... so please ignore my answer as the constraints change things.

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they are logically same :) – Mihran Hovsepyan Mar 25 '11 at 17:37
    
I answered the question before you added the constraint. If you try with mask = 0xff and i=6, you'll find they are far from equal ;-) – Roger Mar 25 '11 at 17:43
    
10 million times isn't even close to what you need to get a timing, much less see any difference. That's why the question is silly! – Bo Persson Mar 25 '11 at 17:53

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