I'm working on a granular dynamics problem. The computationally expensive part is the function below that solve a quadratic equation to detect the collision of two particles.

I was wondering if this can be easily optimized or if I'm doing something noticeably stupid? For example, is it a good idea to use these `const double x1 = p1->x;` constructions to give the compiler a hint? Looking at the assembler code, the compiler uses SSE instructions, but I have no idea if they are optimal in any way (probably not). According to the profiler, most of the time is spend in calculating the expressions `a`, `b` and `c`. What do you (in general) do when you are trying to optimize some kernel function like the one below?

``````void detect_collision_of_pair(struct particle* p1, struct particle* p2){
const double x1  = p1->x;
const double y1  = p1->y;
const double z1  = p1->z;
const double x2  = p2->x;
const double y2  = p2->y;
const double z2  = p2->z;
const double vx1 = p1->vx;
const double vy1 = p1->vy;
const double vz1 = p1->vz;
const double vx2 = p2->vx;
const double vy2 = p2->vy;
const double vz2 = p2->vz;

const double a = vx1*vx1 - 2.*vx1*vx2 + vx2*vx2 + vy1*vy1 - 2.*vy1*vy2 + vy2*vy2 + vz1*vz1 - 2.*vz1*vz2 + vz2*vz2;
const double b = 2.*vx1*x1 - 2.*vx2*x1 - 2.*vx1*x2 + 2.*vx2*x2 + 2.*vy1*y1 - 2.*vy2*y1 - 2.*vy1*y2 + 2.*vy2*y2 + 2.*vz1*z1 - 2.*vz2*z1 - 2.*vz1*z2 + 2.*vz2*z2;
const double c = -4.*particle_radius*particle_radius + x1*x1 - 2.*x1*x2 + x2*x2 + y1*y1 - 2.*y1*y2 + y2*y2 + z1*z1 - 2.*z1*z2 + z2*z2;

double root = b*b-4.*a*c;
if (root>=0.){
root = sqrt(root);
double time1 = (-b-root)/(2.*a);
double time2 = (-b+root)/(2.*a);

if ( (time1>-dt && time1<0.) || (time1<-dt && time2>0) ){
double times = -dt;
if (time1>-dt || time2<0){
if (time1>-dt){
times = time1;
}else{
times = time2;
}
}
resolve_collision(p1,p2,times);
}
}
}
``````
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Thanks everyone. I got a speedup of 30% so far. –  hanno Apr 21 '11 at 15:12

Why have you expanded all the equations? This is not a good idea. Why not compute:

``````vx = v1x-v2x;
vy = v1y-v2y;
vz = v1z-v2z;
a = vx*vx + vy*vy + vz*vz;
``````

This is many fewer operations than what you're doing to compute a for example. The same type of thing can be done for b and c. You can also do similar with the positions, i.e. compute px, py,pz as the differences in positions and then square them.

On another note, get rid of all that const stuff, the compiler doesn't need those for local variables. In fact, you probably don't need to copy to local variables, just create locals for the things you need like the vx,vy,vz above. You're doing way too much here, and that's why the code is taking too much time :-)

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Thanks. That was stupid ;-) –  hanno Apr 20 '11 at 14:42
It happens to everyone from time to time... :-) –  phkahler Apr 20 '11 at 15:25

Wrt to calculating a, b, and c, I don't see anything obviously wrong. Using the temporary variables x1 = p1->x and so forth should neither help nor hurt with a decent optimizing compiler, as in this case there's no aliasing issue (a common performance problem) due to p1 and p2 not being written to, and the compiler will decide which variables to keep in registers when doing the calculations of a,b, and c. If you want to be sure wrt aliasing, you can always mark the arguments as

``````struct particle * const restrict p1
``````

and the same for p2.

I suppose one (minor?) improvement might be to move the multiplications by 2 after the summing, saving some multiplications. E.g.

``````const double b = 2 * (vx1*x1 - vx2*x1 - vx1*x2 + vx2*x2 + vy1*y1 - vy2*y1 - vy1*y2 + vy2*y2 + vz1*z1 - vz2*z1 - vz1*z2 + vz2*z2);
``````

OTOH, one problem with your code is that the calculation of the roots of the quadratic equation with the obvious formula as you have done is prone to catastrophic cancellation. See e.g.

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Thanks for the `const restrict` tip! –  hanno Apr 20 '11 at 14:43
Better yet, why not just bit shift the whole thing, as that will multiply it by two. –  leetNightshade Apr 20 '11 at 14:53
@leetNightshade: Umm, because bit-shifting a floating point value is not equivalent to multiplying by two? Furthermore, even for unsigned integer variables where bit-shifting IS equivalent to multiplying by 2, this is exactly the kind of micro-optimization that the compiler is perfectly capable of doing on its own. –  janneb Apr 21 '11 at 12:03
Right, I knew that. >.> –  leetNightshade Apr 21 '11 at 18:30
By the way, the reason I downvoted is because this wrong information is an endless source of bugs and bad code. We regularly encounter questioners using `float`, presumably with an assumption that there's some reason to prefer it over `double`, and running into problems with default promotions or loss of precision. In any case your answer is not relevant to OP's question. –  R.. Apr 20 '11 at 20:50
The tag `sse` refers to the sse instruction set on x86, used for vectorized math. Single precision `float` has just a 23-bit mantissa, yielding something like 7 decimal places if you convert that to decimal. This means it cannot even store large integer values (greater than a few million) without loss of precision. It also means small accumulated errors could grow large pretty quickly - imagine things like a running windowed average or applying a series of linear transformations... –  R.. Apr 21 '11 at 1:20