# optimization, branching elimination

``````float mixValue = ... //in range -1.0f to 1.0f
for(... ; ... ; ...  ) //long loop
{
float inputLevel = ... //in range -1.0f to 1.0f
if(inputLevel < 0.0 && mixValue < 0.0)
{
mixValue = (mixValue + inputLevel) + (mixValue*inputLevel);
}
else
{
mixValue = (mixValue + inputLevel) - (mixValue*inputLevel);
}
}
``````

just a simple question, can we calculate `mixValue` without branching? or any other optimization suggestion, such as using SIMD?

``````const float sign[] = {-1, 1};
float mixValue = ... //in range -1.0f to 1.0f
for(... ; ... ; ...  ) //long loop
{
float inputLevel = ... //in range -1.0f to 1.0f
unsigned a = *(unsigned*)(&mixValue);
unsigned b = *(unsigned*)(&inputLevel);

float mulValue = mixValue * inputLevel * sign[(a & b) >> (8*sizeof(unsigned)-1)];
float addValue = mixValue + inputLevel;
}
``````

thank you.

-
Are you sure that this is exactly what you want to do? –  sellibitze Aug 2 '10 at 12:56
I'am sure it is, it work perfectly, as for reference you could refer audio wave mixing algorithm for floating point sample in range of [-1.0f,1.0f] –  uray Aug 2 '10 at 13:00
Note that if either `mixValue` or `inputLevel` is 0.0, then both branches are identical. Furthermore, if `inputLevel` is 0.0, you don't actually need to do anything. But I too suspect the formula is wrong. Such formulas typically are either odd or even; either `f(-x)==f(x)` or `f(-x)==-f(x)`. Yours is neither. –  MSalters Aug 2 '10 at 13:06
that's right, if prev `mixValue==0` then `mixValue=inputLevel`, if next `inputLevel==0` then `mixValue` stay unchanged. you can see it as if you mix audible sound and silence sound there will nothing changed. but if you mix two noisy sound, and the peak of those sound is meet you can't add those two value because it will clipped outside max. –  uray Aug 2 '10 at 13:27
This post is old, but I'll comment anyway. You can compute sign with no multiplies with the following: `(float)(-1 + (int)(((a & b) >> (8*sizeof(unsigned)-1)) << 1))` (array indexing has implicit multiply) –  Wug Aug 27 '12 at 20:56

Inspired by Roku's answer (which on MSVC++10 branches), this doesn't seem to branch:

``````#include <iostream>

using namespace std;
const float sign[] = {-1, 1};
int main() {
const int N = 10;
float mixValue = -0.5F;
for(int i = 0; i < N; i++) {
volatile float inputLevel = -0.3F;
int bothNegative = ((((unsigned char*)&inputLevel)[3] & 0x80) & (((unsigned char*)&mixValue)[3] & 0x80)) >> 7;
mixValue = (mixValue + inputLevel) + (sign[bothNegative]*mixValue*inputLevel);
}

std::cout << mixValue << std::endl;
}
``````

Here's the disassembly, as analyzed by IDA Pro (compiled on MSVC++10, Release mode):

-
why u need `volatile`? –  uray Aug 2 '10 at 14:20
Just to make sure the compiler doesn't optimize it away. –  Pedro d'Aquino Aug 2 '10 at 14:25
disclaimer: like most bit twiddling code, it relies on the representation in memory of built-in types (here float) and cannot be assumed to be portable (32 / 64 bits, etc...) –  Matthieu M. Aug 2 '10 at 14:36

``````const float sign[] = {-1, 1};

float mixValue = ... //in range -1.0f to 1.0f
for(... ; ... ; ...  ) //long loop
{
float inputLevel = ... //in range -1.0f to 1.0f
int bothNegative = (inputLevel < 0.0) & (mixValue < 0.0);
mixValue = (mixValue + inputLevel) + (sign[bothNegative]*mixValue*inputLevel);
}
``````

Edit: Mike was correct that && would introduce a branch and thanks for Pedro for proving it. I changed && to & and now GCC (version 4.4.0) generates branch-free code.

-
The problem is : if bothNefative is false, it's equal to 0, so it can never been negative. –  Klaim Aug 2 '10 at 13:29
@Klaim: `sign[0]` is -1, so `sign[bothNegative]` with `bothNegative==0` is -1 –  uray Aug 2 '10 at 13:37
Ah yes I did'nt see the array. That's smart! I spent too much time trying to get something like that and I never thought of predefined values in an array XD So simple... –  Klaim Aug 2 '10 at 13:52
`&&` might introduce a branch; if you really want to be sure, use `&`. –  Mike Seymour Aug 2 '10 at 13:53
Compiled on MSVC++10, Release, this does branch: img641.imageshack.us/img641/7063/floattestbranch.png (IDA screenshot). Replacing `&&` with `&` yields similar results. –  Pedro d'Aquino Aug 2 '10 at 14:05
show 1 more comment
``````float mixValue = ... //in range -1.0f to 1.0f
for(... ; ... ; ...  ) //long loop
{
float inputLevel = ... //in range -1.0f to 1.0f
float mulValue = mixValue * inputLevel;
float addValue = mixValue + inputLevel;
__int32 a = *(__int32*)(&mixValue);
__int32 b = *(__int32*)(&inputLevel);
__int32 c = *(__int32*)(&mulValue);
__int32 d = c & ((a ^ b) | 0x7FFFFFFF);
}
``````
-

Just off the top of my head (I'm sure it can be reduced):

`mixValue = (mixValue + inputLevel) + (((mixValue / fabs(mixValue)) + (inputLevel / fabs(inputLevel))+1) / fabs(((mixValue / fabs(mixValue)) + (inputLevel / fabs(inputLevel))+1)))*-1*(mixValue*inputLevel);`

Just to clarify a bit, I'll calculate sign separately:

``````float sign = (((mixValue / fabs(mixValue)) + (inputLevel / fabs(inputLevel))+1) / fabs(((mixValue / fabs(mixValue)) + (inputLevel / fabs(inputLevel))+1)))*-1;
mixValue = (mixValue + inputLevel) + sign*(mixValue*inputLevel);
``````

This is floating point math, so you'll likely need to correct for some rounding issues, but that should set you on the right path I think.

-
I bet division is even more inefficient than branching. –  KennyTM Aug 2 '10 at 13:17
@NullUserException: `fabs()` can be computed without branching. –  jpalecek Aug 2 '10 at 13:27

If you are worried about excessive branching, look at Duff's Device. This should help unwind the loop somewhat. Truth be told, loop unwinding is something that will be done by the optimizer, so trying to do it by hand may be a waste of time. Check the assembly output to find out.

SIMD will definitely be of assistance provided you a performing the exact same operation to each item in your array. Be aware than not all hardware supports SIMD but some compilers like gcc do provide intrinsics for SIMD which will save your from dipping into assembler.

If you are using gcc to compile ARM code, the SIMD intrinsics can be found here

-
I've seen the asm output, it does unwind the loop, but branching is still there, it create two code path, and no SIMD applied although it used instruction like mulss or addss on xmm reg –  uray Aug 2 '10 at 13:16
The problem with your code is that `mixValue` is changed between iterations, so I guess no SIMD is possible here. –  jpalecek Aug 2 '10 at 13:26

Have you benchmarked the loop with and without the branch ?

At least you could remove one part of the branch, since mixValue is outside of the loop.

``````float multiplier(float a, float b){
unsigned char c1Neg = reinterpret_cast<unsigned char *>(&a)[3] & 0x80;
unsigned char c2Neg = reinterpret_cast<unsigned char *>(&b)[3] & 0x80;
unsigned char multiplierIsNeg = c1Neg & c2Neg;
float one = 1;
reinterpret_cast<unsigned char *>(&one)[3] |= multiplierIsNeg;
return -one;
}
cout << multiplier(-1,-1) << endl; // +1
cout << multiplier( 1,-1) << endl; // -1
cout << multiplier( 1, 1) << endl; // -1
cout << multiplier(-1, 1) << endl; // -1
``````
-
my question is to eliminate branch, the benchmark result is out of this question. –  uray Aug 2 '10 at 12:57
`mixValue` is loop dependent variable see: `mixValue = (mixValue + ...` –  uray Aug 2 '10 at 12:58
you're right. Sorry. –  tibur Aug 2 '10 at 13:02
That should do the trick with only four bitwise operations. –  tibur Aug 2 '10 at 13:38

Looking at your code, you see that you will always add the absolute value of `mixValue` and `inputLevel`, except when both are positive.

With some bit-fiddling and IEEE floatingpoint knowledge, you may get rid of the conditional:

``````// sets the first bit of f to zero => makes it positive.
void absf( float& f ) {
assert( sizeof( float ) == sizeof( int ) );
reinterpret_cast<int&>( f ) &= ~0x80000000;
}

// returns a first-bit = 1 if f is positive
int pos( float& f ) {
return ~(reinterpret_cast<int&>(f) & 0x80000000) & 0x80000000;
}

// returns -fabs( f*g ) if f>0 and g>0, fabs(f*g) otherwise.
float prod( float& f, float& g ) {
float p = f*g;
float& rp=p;
int& ri = reinterpret_cast<int&>(rp);
absf(p);
ri |= ( pos(f) & pos(g) & 0x80000000); // first bit = + & +
return p;
}

int main(){
struct T { float f, g, r;
void test() {
float p = prod(f,g);
float d = (p-r)/r;
assert( -1e-15 < d && d < 1e-15 );
}
};
T vals[] = { {1,1,-1},{1,-1,1},{-1,1,1},{-1,-1,1} };
for( T* val=vals; val != vals+4; ++val ) {
val->test();
}
}
``````

``````for( ... ) {
mixedResult += inputLevel + prod(mixedResult,inputLevel);
}
``````

Note: the dimensions of your accumulation don't match. The `inputLevel` is a dimensionless quantity, while `mixedResult` is your... result (e.g. in Pascal, in Volts, ...). You cannot add two quantities with different dimensions. Probably you want `mixedResult += prod( mixedResult, inputLevel )` as your accumulator.

-

Some compilers (ie MSC) would also require manual sign checking.

Source:

``````volatile float mixValue;
volatile float inputLevel;

float u   = mixValue*inputLevel;
float v   = -u;
float a[] = { v, u };

mixValue = (mixValue + inputLevel) + a[ (inputLevel<0.0) & (mixValue<0.0) ];
``````

IntelC 11.1:

``````movss     xmm1, DWORD PTR [12+esp]
mulss     xmm1, DWORD PTR [16+esp]
movss     xmm6, DWORD PTR [12+esp]
movss     xmm2, DWORD PTR [16+esp]
movss     xmm3, DWORD PTR [16+esp]
movss     xmm5, DWORD PTR [12+esp]
xorps     xmm4, xmm4
movaps    xmm0, xmm4
subss     xmm0, xmm1
movss     DWORD PTR [esp], xmm0
movss     DWORD PTR [4+esp], xmm1
xor       eax, eax
cmpltss   xmm3, xmm4
movd      ecx, xmm3
neg       ecx
cmpltss   xmm5, xmm4
movd      edx, xmm5
neg       edx
and       ecx, edx
movss     DWORD PTR [12+esp], xmm6
``````

gcc 4.5:

``````flds    32(%esp)
flds    16(%esp)
fmulp   %st, %st(1)
fld     %st(0)
fchs
fstps   (%esp)
fstps   4(%esp)
flds    32(%esp)
flds    16(%esp)
flds    16(%esp)
flds    32(%esp)
fxch    %st(2)
fldz
fcomi   %st(2), %st
fstp    %st(2)
fxch    %st(1)
seta    %dl
xorl    %eax, %eax
fcomip  %st(1), %st
fstp    %st(0)
seta    %al
andl    %edx, %eax