# Branching elimination using bitwise operators

I have some critical branching code inside a loop that's run about 2^26 times. Branch prediction is not optimal because `m` is random. How would I remove the branching, possibly using bitwise operators?

``````bool m;
unsigned int a;
const unsigned int k = ...; // k >= 7
if(a == 0)
a = (m ? (a+1) : (k));
else if(a == k)
a = (m ?     0 : (a-1));
else
a = (m ? (a+1) : (a-1));
``````

And here is the relevant assembly generated by `gcc -O3`:

``````.cfi_startproc
movl    4(%esp), %edx
movb    8(%esp), %cl
movl    (%edx), %eax
testl   %eax, %eax
jne L15
cmpb    \$1, %cl
sbbl    %eax, %eax
andl    \$638, %eax
incl    %eax
movl    %eax, (%edx)
ret
L15:
cmpl    \$639, %eax
je  L23
testb   %cl, %cl
jne L24
decl    %eax
movl    %eax, (%edx)
ret
L23:
cmpb    \$1, %cl
sbbl    %eax, %eax
andl    \$638, %eax
movl    %eax, (%edx)
ret
L24:
incl    %eax
movl    %eax, (%edx)
ret
.cfi_endproc
``````
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Before you jump into this, you might want to make sure the compilers you care about aren't actually able to optimize these into conditional moves. – Mysticial Aug 19 '12 at 21:09
Is 0<=a<=k a valid assumption? – Eric Aug 19 '12 at 21:13
@Eric Yes, 0<=a<=k is always true. – scientiaesthete Aug 19 '12 at 21:16
I'm quite surprised that GCC isn't able to turn the inner branches into conditional moves. The ones you have here are a lot simpler than the one in this question where `-O3` does the job. – Mysticial Aug 19 '12 at 21:35
Looks like it's basically `a = a + (m?1:-1) % k`; One branch which a two-element LUT could fix. Or have I got negative modulo wrong...? – Roddy Aug 19 '12 at 22:10

The branch-free division-free modulo could have been useful, but testing shows that in practice, it isn't.

``````const unsigned int k = 639;
void f(bool m, unsigned int &a)
{
a += m * 2 - 1;
if (a == -1u)
a = k;
else if (a == k + 1)
a = 0;
}
``````

Testcase:

``````unsigned a = 0;
f(false, a);
assert(a == 639);
f(false, a);
assert(a == 638);
f(true, a);
assert(a == 639);
f(true, a);
assert(a == 0);
f(true, a);
assert(a == 1);
f(false, a);
assert(a == 0);
``````

Actually timing this, using a test program:

``````int main()
{
for (int i = 0; i != 10000; i++)
{
unsigned int a = k / 2;
while (a != 0) f(rand() & 1, a);
}
}
``````

(Note: there's no `srand`, so results are deterministic.)

The code in the question: 4.8s

Lookup table: 4.5s (`static unsigned lookup[2][k+1];`)

Lookup table: 4.3s (`static unsigned lookup[k+1][2];`)

This version: 4.0s

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Wow! Your version is indeed faster than mine and others, it shaved about 7 nanosecs off of 30 nanosecs / loop. Great improvement! Thanks for all your effort! – scientiaesthete Aug 19 '12 at 23:02

The fastest I've found is now the table implementation

Timings I got (UPDATED for new measurement code)

HVD's most recent: 9.2s

Table version: 7.4s (with k=693)

Table creation code:

``````    unsigned int table[2*k];
table_ptr = table;
for(int i = 0; i < k; i++){
unsigned int a = i;
f(0, a);
table[i<<1] = a;

a = i;
f(1, a);
table[i<<1 + 1] = a;
}
``````

Table runtime loop:

``````void f(bool m, unsigned int &a){
a = table_ptr[a<<1 | m];
}
``````

With HVD's measurement code, I saw the cost of the rand() dominating the runtime, so that the runtime for a branchless version was about the same range as these solutions. I changed the measurement code to this (UPDATED to keep random branch order, and pre-computing random values to prevent rand(), etc. from trashing the cache)

``````int main(){
unsigned int a = k / 2;
int m[100000];
for(int i = 0; i < 100000; i++){
m[i] = rand() & 1;
}

for (int i = 0; i != 10000; i++
{
for(int j = 0; j != 100000; j++){
f(m[j], a);
}
}
}
``````
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Nice! I created a test program and measured, the original version takes ~4.8s, my branch-free version takes ~5.3s so doesn't buy anything (which I had noted in my now deleted answer), yours takes ~4.2s. – hvd Aug 19 '12 at 22:19
Wow. The branch-free division-free modulo is still worse than branching. See my new answer. – hvd Aug 19 '12 at 22:32
I'm not seeing the benefits you get in your latest version. Yes, `rand()` will take up most of the time, but the time it's taking should be constant, so that doesn't matter, the absolute difference between the different versions is still a useful measurement. I get ~4.3s with that version. – hvd Aug 19 '12 at 23:21
Either way, I just checked and think a table-lookup significantly beats both of our solutions. – Eric Aug 19 '12 at 23:33
I already included that in my tests, and it doesn't (probably because it accesses memory in an unpredictable order). – hvd Aug 19 '12 at 23:38

I don't think you can remove the branches entirely, but you can reduce the number by branching on m first.

``````if (m){
if (a==k) {a = 0;} else {++a;}
}
else {
if (a==0) {a = k;} else {--a;}
}
``````
-

``````if (a==k) {a = 0;} else {++a;}
``````

looks like an increase with wraparound. You can write this as

``````a=(a+1)%k;
``````

which, of course, only makes sense if divisions are actually faster than branches.

Not sure about the other one; too lazy to think about what the (~0)%k will be.

-
+1, gcc optimises divisions by constants very well (replacing it by multiplications that rely on integer overflow), but it should be `% (k + 1)`. For the subtraction, just add another `k + 1` before subtracting 1 and getting the remainder: `a = (a + k) % (k + 1);` – hvd Aug 19 '12 at 21:57
I've expanded on your answer in my own. – hvd Aug 19 '12 at 22:02

This has no branches. Because K is constant, compiler might be able to optimize the modulo depending on it's value. And if K is 'small' then a full lookup table solution would probably be even faster.

``````bool m;
unsigned int a;
const unsigned int k = ...; // k >= 7
const int inc[2] = {1, k};

a = a + inc[m] % (k+1);
``````
-

If k isn't large enough to cause overflow, you could do something like this:

``````int a; // Note: not unsigned int
int plusMinus = 2 * m - 1;
a += plusMinus;
if(a == -1)
a = k;
else if (a == k+1)
a = 0;
``````

Still branches, but the branch prediction should be better, since the edge conditions are rarer than m-related conditions.

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