This is a textbook question that involves rewriting some C code to make it perform best on a given processor architecture.

Given: targeting a single superscalar processor with 4 adders and 2 multiplier units.

Input structure (initialized elsewhere):

```
struct s {
short a;
unsigned v;
short b;
} input[100];
```

Here is the routine to operate on this data. Obviously correctness must be ensured, but the goal is to optimize the crap out of it.

```
int compute(int x, int *r, int *q, int *p) {
int i;
for(i = 0; i < 100; i++) {
*r *= input[i].v + x;
*p = input[i].v;
*q += input[i].a + input[i].v + input[i].b;
}
return i;
}
```

So this method has 3 arithmetic instructions to update the integers r, q, p.

Here's my attempt with comments explaining what I'm thinking:

```
//Use temp variables so we don't keep using loads and stores for mem accesses;
//hopefully the temps will just be kept in the register file
int r_temp = *r;
int q_temp = *q;
for (i=0;i<99;i = i+2) {
int data1 = input[i];
int data2 = input[i+1]; //going to try partially unrolling loop
int a1 = data1.a;
int a2 = data2.a;
int b1 = data1.b;
int b2 = data2.b;
int v1 = data1.v;
int v2 = data2.v;
//I will use brackets to make my intention clear the order of operations I was planning
//with respect to the functional (adder, mul) units available
//This is calculating the next iteration's new q value
//from q += v1 + a1 + b1, or q(new)=q(old)+v1+a1+b1
q_temp = ((v1+q1)+(a1+b1)) + ((a2+b2)+v2);
//For the first step I am trying to use a max of 3 adders in parallel,
//saving one to start the next computation
//This is calculating next iter's new r value
//from r *= v1 + x, or r(new) = r(old)*(v1+x)
r_temp = ((r_temp*v1) + (r_temp*x)) + (v2+x);
}
//Because i will end on i=98 and I only unrolled by 2, I don't need to
//worry about final few values because there will be none
*p = input[99].v; //Why it's in the loop I don't understand, this should be correct
*r = r_temp;
*q = q_temp;
```

Ok so what did my solution give me? Looking at the old code, each loop iteration of i will take the minimum latency of max((1A + 1M),(3A)) where the former value is for calculating the new r while the latency of 3 Adds is for q.

In my solution, I am unrolling by 2 and trying to calculate the 2nd new value of r and q. Assuming the the latency of adders/multipliers is such that M = c*A (c is some integer > 1), the multiply operations for r are definitely the rate-limiting step, so I focus on that. I tried to use the multipliers in parallel as much as I could.

In my code, 2 multipliers are used at first in parallel to help calculate intermediate steps, then an add must combine those, then a final multiply is used for obtaining the last result. So for 2 new values of r (even though I only keep/care about the last one), it takes me (1M // 1M // 1A) + 1A + 1M, for a total latency of 2M + 1M sequentially. Dividing by 2, my **latency per loop value is 1M + 0.5A**. I calculate the original latency/value (for r) to be 1A + 1M. So if my code is correct (I did this all by hand, haven't tested yet!) then I have a small performance boost.

Also, hopefully by not accessing and updating pointers directly in the loop as much (thanks to temp variables r_temp and q_temp mainly), I save on some load/store latency.

That was my stab at it. Definitely interested in seeing what others come up with that's better!

`-O0`

for no optimization, there were 40 arithmetic ops per loop. With`-O3`

, 25 of them were eliminated, leaving 15. – twalberg Sep 11 '12 at 19:49