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I have the following tight loop that makes up the serial bottle neck of my code. Ideally I would parallelize the function that calls this but that is not possible.

//n is about 60
for (int k = 0;k < n;k++) 
    double fone = z[k*n+i+1];
    double fzer = z[k*n+i];
    z[k*n+i+1]= s*fzer+c*fone;
    z[k*n+i] = c*fzer-s*fone;

Are there any optimizations that can be made such as vectorization or some evil inline that can help this code?

I am looking into finding eigen solutions of tridiagonal matrices. http://www.cimat.mx/~posada/OptDoglegGraph/DocLogisticDogleg/projects/adjustedrecipes/tqli.cpp.html

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Non-sequential memory access. Period. – Mysticial Dec 16 '12 at 10:23
What is i? Is there a loop involving it? – NPE Dec 16 '12 at 10:25
Do you have an outer loop over i? – chill Dec 16 '12 at 10:25
Would you mind coming up with self-contained example we can compile and experiment with? – NPE Dec 16 '12 at 10:25
Try allocating fone and fzer outside of the loop, then setting them inside the loop. Most likely they will compile into two push and then pop instructions. You could also use a pointer to store the two array indices so you don't have to calculate kn+i and kn+i+1 twice every time. – user1158559 Dec 16 '12 at 10:28
up vote 8 down vote accepted

Short answer: Change the memory layout of your matrix from row-major order to column-major order.

Long answer: It seems you are accessing the (i)th and (i+1)th column of a matrix stored in row-major order - probably a big matrix that doesn't as a whole fit into CPU cache. Basically, on every loop iteration the CPU has to wait for RAM (in the order of hundred cycles). After a few iteraterations, theoretically, the address prediction should kick in and the CPU should speculatively load the data items even before the loop acesses them. That should help with RAM latency. But that still leaves the problem that the code uses the memory bus inefficiently: CPU and memory never exchange single bytes, only cache-lines (64 bytes on current processors). Of every 64 byte cache-line loaded and stored your code only touches 16 bytes (or a quarter).

Transposing the matrix and accessing it in native major order would increase memory bus utilization four-fold. Since that is probably the bottle-neck of your code, you can expect a speedup of about the same order.

Whether it is worth it, depends on the rest of your algorithm. Other parts may of course suffer because of the changed memory layout.

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Could you expand a bit more on "Of every 64 byte cache-line loaded and stored your code only touches 16 bytes (or a quarter)." I don't understand why only 16 bytes touch the memory bus... – Mikhail Dec 16 '12 at 11:50
Well, during a memory transaction, the CPU never loads or stores anything less than a cache-line (64 bytes). Your code loads and stores 16 consecutive bytes: z[kn+i], z[kn+i+1]. However, the CPU doesn't load 16 bytes, it loads 64 bytes - the particular cache-line that contains the data. Of these 64 bytes, 48 are loaded and stored in vein. They take up valuable bus-resources, but your code cannot take advantage. – edgar.holleis Dec 16 '12 at 12:02

I take it you are rotating something (or rather, lots of things, by the same angle (s being a sin, c being a cos))?

Counting backwards is always good fun and cuts out variable comparison for each iteration, and should work here. Making the counter the index might save a bit of time also (cuts out a bit of arithmetic, as said by others).

for (int k = (n-1) * n + i; k >= 0; k -= n)
    double fone=z[k+1];
    double fzer=z[k];
    z[k]  =c*fzer-s*fone;

Nothing dramatic here, but it looks tidier if nothing else.

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I tried the run and I didn't notice much of a difference. By the way I am working on finding the eigen values of a tridiagonal matrix system. – Mikhail Dec 16 '12 at 10:42

As first move i'd cache pointers in this loop:

//n is about 60
double *cur_z = &z[0*n+i]
for (int k = 0;k < n;k++) 
    double fone = *(cur_z+1);
    double fzer = *cur_z;
    *(cur_z+1)= s*fzer+c*fone;
    *cur_z = c*fzer-s*fone;
    cur_z += n;

Second, i think its better to make templatized version of this function. As a result, you can get good perfomance benefit if your matrix holds integer values (since FPU operations are slower).

share|improve this answer
What do you mean by templatized version, do you mean that I should unroll the entire for loop (I might be able to do that...)? Also what do you mean by integers. – Mikhail Dec 16 '12 at 11:07
Your matrix holds double values. If you can manage to deal without double-s its will work faster – PSIAlt Dec 16 '12 at 11:09

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