# is i=(i+1)&3 faster than i=(i+1)%4

I am optimizing a c++ code. at one critical step, I want to implement the following function `y=f(x)`:

``````f(0)=1

f(1)=2

f(2)=3

f(3)=0
``````

which one is faster ? using a lookup table or `i=(i+1)&3` or `i=(i+1)%4` ? or any better suggestion?

-
Why don't you try both and measure? Also see: stackoverflow.com/questions/8316332/… –  Beginner Dec 5 '11 at 21:27
The best way to find out is measure. Checking the generated code will probably tell you that they are equal. If you really want to indulge in micro-optimisations: avoid the function and make it a macro or an inlined function. –  wildplasser Dec 5 '11 at 21:31
Thanks everyone. All the comments were right and quite useful. –  mghandi Dec 5 '11 at 21:41
to answer those who asked why I didn't just tried both: I hoped someone may come with an out of the box solution to this, that I hadn't thought of. thanks anyways. –  mghandi Dec 5 '11 at 21:44

Almost certainly the lookup table is going to be slowest. In a lot of cases, the compiler will generate the same assembly for `(i+1)&3` and `(i+1)%4`; however depending on the type/signedness of i, they may not be strictly equivalent and the compiler won't be able to make that optimization. For example for the code

``````int foo(int i)
{
return (i+1)%4;
}

unsigned bar(unsigned i)
{
return (i+1)%4;
}
``````

on my system, `gcc -O2` generates:

``````0000000000000000 <foo>:
0:   8d 47 01                lea    0x1(%rdi),%eax
3:   89 c2                   mov    %eax,%edx
5:   c1 fa 1f                sar    \$0x1f,%edx
8:   c1 ea 1e                shr    \$0x1e,%edx
d:   83 e0 03                and    \$0x3,%eax
10:   29 d0                   sub    %edx,%eax
12:   c3                      retq

0000000000000020 <bar>:
20:   8d 47 01                lea    0x1(%rdi),%eax
23:   83 e0 03                and    \$0x3,%eax
26:   c3                      retq
``````

so as you can see because of the rules about signed modulus results, `(i+1)%4` generates a lot more code in the first place.

Bottom line, you're probably best off using the `(i+1)&3` version if that expresses what you want, because there's less chance for the compiler to do something you don't expect.

-
+1, you are correct. I never realized this difference. –  Mysticial Dec 5 '11 at 21:42

I won't get into the discussion of premature optimization. But the answer is that they will be the same speed.

Any sane compiler will compile them to the same thing. Division/modulus by a power of two will be optimized to bitwise operations anyway.

So use whichever you find (or others will find) to be more readable.

EDIT : As Roland has pointed out, it does sometimes behave different depending on the signness:

Unsigned &:

``````int main(void)
{
unsigned x;
cin >> x;
x = (x + 1) & 3;
cout << x;

return 0;
}

mov eax, DWORD PTR _x\$[ebp]
inc eax
and eax, 3
push    eax
``````

Unsigned Modulus:

``````int main(void)
{
unsigned x;
cin >> x;
x = (x + 1) % 4;
cout << x;

return 0;
}

mov eax, DWORD PTR _x\$[ebp]
inc eax
and eax, 3
push    eax
``````

Signed &:

``````int main(void)
{
int x;
cin >> x;
x = (x + 1) & 3;
cout << x;

return 0;
}

mov eax, DWORD PTR _x\$[ebp]
inc eax
and eax, 3
push    eax
``````

Signed Modulus:

``````int main(void)
{
int x;
cin >> x;
x = (x + 1) % 4;
cout << x;

return 0;
}

mov eax, DWORD PTR _x\$[ebp]
inc eax
and eax, -2147483645            ; 80000003H
jns SHORT \$LN3@main
dec eax
or  eax, -4                 ; fffffffcH
``````
-
I don't think any compiler is smart enough to turn the lookup table into the same code as modulus/and. And see my answer for why the `%` and the `&` versions might generate different code. –  Roland Dec 5 '11 at 21:33
I forgot to mention the lookup table, but yes, the compiler will not likely to be able to optimize it. –  Mysticial Dec 5 '11 at 21:35

Good chances are, you wouldn't find any differences: any reasonably modern compiler knows to optimize both into the same code.

-

Have you tried benchmarking it? As an offhand gues, I'll assume that the `&3` version will be faster, as that's a simple addition and bitwise AND operation, both of which should be single-cycle operations on any modern-ish CPU.

The `%4` could go a few different ways, depending on how smart the compiler is. it could be done via division, which is much slower than addition, or it could be translated into a bitwise `and` operation as well and end up being just as fast as the `&3` version.

-

same as Mystical but C and ARM

``````int fun1 ( int i )
{
return( (i+1)&3 );
}

int fun2 ( int i )
{
return( (i+1)%4 );
}

unsigned int fun3 ( unsigned int i )
{
return( (i+1)&3 );
}

unsigned int fun4 ( unsigned int i )
{
return( (i+1)%4 );
}
``````

creates:

``````00000000 <fun1>:
0:   e2800001    add r0, r0, #1
4:   e2000003    and r0, r0, #3
8:   e12fff1e    bx  lr

0000000c <fun2>:
c:   e2802001    add r2, r0, #1
10:   e1a0cfc2    asr ip, r2, #31
14:   e1a03f2c    lsr r3, ip, #30
18:   e0821003    add r1, r2, r3
1c:   e2010003    and r0, r1, #3
20:   e0630000    rsb r0, r3, r0
24:   e12fff1e    bx  lr

00000028 <fun3>:
28:   e2800001    add r0, r0, #1
2c:   e2000003    and r0, r0, #3
30:   e12fff1e    bx  lr

00000034 <fun4>:
34:   e2800001    add r0, r0, #1
38:   e2000003    and r0, r0, #3
3c:   e12fff1e    bx  lr
``````

For negative numbers the mask and the modulo are not equivalent, only for positive/unsigned numbers. For those cases your compiler should know that %4 is the same as &3 and use the less expensive on (&3) as gcc above. clang/llc below

``````fun3:
and r0, r0, #3
mov pc, lr

fun4:
and r0, r0, #3
mov pc, lr
``````
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-1, `i=(++i)&3` is in fact invalid (two writes, neither of which is sequenced-before the other). –  MSalters Dec 6 '11 at 9:54