0

I have a function like this in C (in pseudo-ish code, dropping the unimportant parts):

int func(int s, int x, int* a, int* r) {
    int i;

    // do some stuff

    for (i=0;i<a_really_big_int;++i) {
        if (s) r[i] = x ^ i;
        else r[i] = x ^ a[i];
        // and maybe a couple other ways of computing r
        // that are equally fast individually
    }

    // do some other stuff

}

This code gets called so much that this loop is actually a speed bottleneck in the code. I am wondering a couple things:

  1. Since the switch s is a constant in the function, will good compilers optimize the loop so that the branch isn't slowing things down all the time?

  2. If not, what is a good way to optimize this code?

====

Here is an update with a fuller example:

int func(int s,
         int start,int stop,int stride,
         double *x,double *b,
         int *a,int *flips,int *signs,int i_max,
         double *c)
{
  int i,k,st;
  for (k=start; k<stop; k += stride) {
    b[k] = 0;
    for (i=0;i<i_max;++i) {

      /* this is the code in question */
      if (s) st = k^flips[i];
      else st = a[k]^flips[i];
      /* done with code in question */

      b[k] += x[st] * (__builtin_popcount(st & signs[i])%2 ? -c[i] : c[i]);
    }
  }
}

EDIT 2:

In case anyone is curious, I ended up refactoring the code and hoisting the whole inner for loop (with i_max) outside, making the really_big_int loop be much simpler and hopefully easy to vectorize! (and also avoiding doing a bunch of extra logic a zillion times)

  • 2
    If possible, do two if statements, each containing a loop, instead of a loop containing two if statements. Then you only check the condition once, not a_really_big_int times. This depends on the other things in your current loop being "extractable" in this way. – hnefatl Oct 6 '17 at 23:09
  • 1
    @hnefatl right---the reason that I wanted to avoid that is because the actual loop is several nested loops with some not-totally-trivial logic, and I don't want to have to duplicate code a bunch of times. But maybe this is the best solution – G. Meyer Oct 6 '17 at 23:11
  • 2
    @Barmar The example given becomes trivially vectorizable, so gcc absolutely hoists the if() out of the loop. – EOF Oct 6 '17 at 23:15
  • 1
    @EOF But maybe his actual code isn't exactly like the example given. He said he left out "unimportant" parts. They might be important to the GCC optimizer. – Barmar Oct 6 '17 at 23:17
  • 1
    @G.Meyer You can just make all variables be function arguments for all I care. The only point is that I can throw it at my compiler and get a result everybody else can verify (unlike when I have to take a hacksaw to your code to test it). – EOF Oct 6 '17 at 23:42
4

One obvious way to optimize the code is pull the conditional outside the loop:

if (s)
    for (i=0;i<a_really_big_int;++i) {
        r[i] = x ^ i;
    }
else
    for (i=0;i<a_really_big_int;++i) {
        r[i] = x ^ a[i];
    }

A shrewd compiler might be able to change that into r[] assignments of more than one element at a time.

  • A "shrewd compiler" doesn't need the help, it can hoist the if() just fine. – EOF Oct 6 '17 at 23:45
  • 1
    @EOF: You missed my point. I am talking about what happens after the if is hoisted. – wallyk Oct 6 '17 at 23:46
  • 1
    ... and now it can be vectorized with _mm*_xor_si*(), _mm*_set_epi32() and unaligned load/stores (unless you can insure the inputs are aligned) , but hopefully the compiler can do it itself – technosaurus Oct 7 '17 at 16:15
2

Micro-optimizations

Usually they are not worth the time - reviewing larger issue is more effective.

Yet to micro-optimize, trying a variety of approaches and then profiling them to find the best can make for modest improvements.

In addition to @wallyk and @kabanus fine answers, some simplistic compilers benefit with a loop that ends in 0.

// for (i=0;i<a_really_big_int;++i) {
for (i=a_really_big_int; --i; ) {

[edit 2nd optimization]

OP added a more compete example. One of the issues is that the compiler can not make assumption that that the memory pointed to by b and others do not overlap. This prevents certain optimizations.

Assuming they in fact to do not overlap, use restrict on b to allow optimizations. const helps too for weaker compilers that do no deduce that. restrict on the others may also benefit, again, if the reference data does not overlap.

// int func(int s, int start, int stop, int stride, double *x,
//     double *b, int *a, int *flips,
//     int *signs, int i_max, double *c) {

int func(int s, int start, int stop, int stride, const double * restrict x,
    double * restrict b, const int * restrict a, const int * restrict flips, 
    const int * restrict signs, int i_max, double *c) {
  • thanks, the use of restrict is a really good idea! – G. Meyer Oct 9 '17 at 19:09
1

All your commands are quick O(1) command in the loop. The if is definitely optimized, so is your for+if if all your commands are of the form r[i]=somethingquick. The question may boil down for you on how small can big int be?

A quick int main that just goes from INT_MIN to INT_MAX summing into a long variable, takes ~10 seconds for me on the Ubuntu subsystem on Windows. Your commands may multiply this by a few, which quickly gets to a minute. Bottom line, this may be not be avoidable if you really are iterating a ton.

If r[i] are calculated independently, this would be a classic usage for threading/multi-processing.

EDIT:

I think % is optimized anyway by the compiler, but if not, take care that x & 1 is much faster for an odd/even check.

  • re: the builtin, I think that depending on your architecture __builtin_popcount is a single machine instruction (from gcc) anyway. I'm not sure though. anyway I really doubt that the hamming weight of an int takes a lot of time to compute... – G. Meyer Oct 6 '17 at 23:41
  • @G.Meyer It is (returns the 1s or something). Didn't know for sure it was a single instruction though, thanks. – kabanus Oct 6 '17 at 23:45
1

Assuming x86_64, you can ensure that the pointers are aligned to 16 bytes and use intrinsics. If it is only running on systems with AVX2, you could use the __mm256 variants (similar for avx512*)

int func(int s, int x, const __m128i* restrict a, __m128i* restrict r) {
    size_t i = 0, max = a_really_big_int / 4;
    __m128i xv =  _mm_set1_epi32(x);
    // do some stuff
    if (s) {
        __m128i iv = _mm_set_epi32(3,2,1,0); //or is it 0,1,2,3?
        __m128i four = _mm_set1_epi32(4);
        for ( ;i<max; ++i, iv=_mm_add_epi32(iv,four)) {
            r[i] = _mm_xor_si128(xv,iv);
        }
    }else{ /*not (s)*/
        for (;i<max;++i){
            r[i] = _mm_xor_si128(xv,a[i]);
        }
    }
    // do some other stuff   
}
0

Although the if statement will be optimized away on any decent compiler (unless you asked the compiler not to optimize), I would consider writing the optimization in (just in case you compile without optimizations).

In addition, although the compiler might optimize the "absolute" if statement, I would consider optimizing it manually, either using any available builtin, or using bitwise operations.

i.e.

b[k] += x[st] *
        ( ((__builtin_popcount(st & signs[I]) & 1) *
           ((int)0xFFFFFFFFFFFFFFFF)) ^c[I] );

This will take the last bit of popcount (1 == odd, 0 == even), multiply it by the const (all bits 1 if odd, all bits 0 if true) and than XOR the c[I] value (which is the same as 0-c[I] or ~(c[I]).

This will avoid instruction jumps in cases where the second absolute if statement isn't optimized.

P.S.

I used an 8 byte long value and truncated it's length by casting it to an int. This is because I have no idea how long an int might be on your system (it's 4 bytes on mine, which is 0xFFFFFFFF).

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.