I was reading Agner Fog's optimization manuals, and I came across this example:

```
double data[LEN];
void compute()
{
const double A = 1.1, B = 2.2, C = 3.3;
int i;
for(i=0; i<LEN; i++) {
data[i] = A*i*i + B*i + C;
}
}
```

Agner indicates that there's a way to optimize this code - by realizing that the loop can avoid using costly multiplications, and instead use the "deltas" that are applied per iteration.

I use a piece of paper to confirm the theory, first...

...and of course, he is right - in each loop iteration we can compute the new result based on the old one, by adding a "delta". This delta starts at value "A+B", and is then incremented by "2*A" on each step.

So we update the code to look like this:

```
void compute()
{
const double A = 1.1, B = 2.2, C = 3.3;
const double A2 = A+A;
double Z = A+B;
double Y = C;
int i;
for(i=0; i<LEN; i++) {
data[i] = Y;
Y += Z;
Z += A2;
}
}
```

In terms of operational complexity, the difference in these two versions of the function is indeed, striking. Multiplications have a reputation for being significantly slower in our CPUs, compared to additions. And we have replaced 3 multiplications and 2 additions... with just 2 additions!

So I go ahead and add a loop to execute `compute`

a lot of times - and then keep the minimum time it took to execute:

```
unsigned long long ts2ns(const struct timespec *ts)
{
return ts->tv_sec * 1e9 + ts->tv_nsec;
}
int main(int argc, char *argv[])
{
unsigned long long mini = 1e9;
for (int i=0; i<1000; i++) {
struct timespec t1, t2;
clock_gettime(CLOCK_MONOTONIC_RAW, &t1);
compute();
clock_gettime(CLOCK_MONOTONIC_RAW, &t2);
unsigned long long diff = ts2ns(&t2) - ts2ns(&t1);
if (mini > diff) mini = diff;
}
printf("[-] Took: %lld ns.\n", mini);
}
```

I compile the two versions, run them... and see this:

```
gcc -O3 -o 1 ./code1.c
gcc -O3 -o 2 ./code2.c
./1
[-] Took: 405858 ns.
./2
[-] Took: 791652 ns.
```

Well, that's unexpected. Since we report the minimum time of execution, we are throwing away the "noise" caused by various parts of the OS. We also took care to run in a machine that does absolutely nothing. And the results are more or less repeatable - rerunning the two binaries shows this is a consistent result:

```
for i in {1..10} ; do ./1 ; done
[-] Took: 406886 ns.
[-] Took: 413798 ns.
[-] Took: 405856 ns.
[-] Took: 405848 ns.
[-] Took: 406839 ns.
[-] Took: 405841 ns.
[-] Took: 405853 ns.
[-] Took: 405844 ns.
[-] Took: 405837 ns.
[-] Took: 406854 ns.
for i in {1..10} ; do ./2 ; done
[-] Took: 791797 ns.
[-] Took: 791643 ns.
[-] Took: 791640 ns.
[-] Took: 791636 ns.
[-] Took: 791631 ns.
[-] Took: 791642 ns.
[-] Took: 791642 ns.
[-] Took: 791640 ns.
[-] Took: 791647 ns.
[-] Took: 791639 ns.
```

The only thing to do next, is to see what kind of code the compiler created for each one of the two versions.

`objdump -d -S`

shows that the first version of `compute`

- the "dumb", yet somehow fast code - has a loop that looks like this:

What about the second, optimized version - that does just two additions?

Now I don't know about you, but speaking for myself, I am... puzzled. The second version has approximately 4 times fewer instructions, with the two major ones being just SSE-based additions (`addsd`

). The first version, not only has 4 times more instructions... it's also full (as expected) of multiplications (`mulpd`

).

I confess I did not expect that result. Not because I am a fan of Agner (I am, but that's irrelevant).

Any idea what I am missing? Did I make any mistake here, that can explain the difference in speed? Note that I have done the test on a Xeon W5580 and a Xeon E5-1620 - in both, the first (dumb) version is much faster than the second one.

For easy reproduction of the results, there are two gists with the two versions of the code: Dumb yet somehow faster and optimized, yet somehow slower.

P.S. Please don't comment on floating point accuracy issues; that's not the point of this question.

`4*A2`

or something like that. Possibly clang could do that for you with`-ffast-math`

(or possibly even GCC, but GCC tends to unroll without multiple accumulators.) With FMA available on Haswell or later, Horner's method would be great for such a short polynomial, easy for out-of-order exec to hide, although it would still need an FP version of`i`

`significand = sig1 * sig2; exponent = exp1+exp2`

), and for floating point addition it needs to be done in series (determine result exponent, then "shift" both values to match the result exponent, then determine result significand).`mulpd`

vs.`addpd`

(and`vfma...`

) Alder Lake improved`addpd`

latency to 3 cycles, down from 4 which was the latency for addpd/subpd/mulpd/vfma...pd since Skylake. AMD has had lower adds on some CPUs, but Zen2 has 3-cycle latency addpd and mulpd vs. 5c fma, like Broadwell7more comments