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This question have a lack of details. So, i decided to create another question instead edit this one. The new question is here: Can i parallelize my code or it is not worth?

I have a program running in CUDA, where one piece of the code is running within a loop (serialized, as you can see below). This piece of code is a search within an array that contain addresses and/or NULL pointers. All the threads execute this code below.

while (i < n) {
    if (array[i] != NULL) {
        return array[i];
    }
    i++;
}
return NULL;

Where n is the size of array and array is in shared memory. I'm only interested in the first address that is different from NULL (first match).

The whole code (i've posted only a piece, the whole code is big) is running fast, but the "heart" of the code (i.e, the part that is more repeated) is serialized, as you can see. I want to know if i can parallelize this part (the search) with some optimized algorithm.

Like i said, the program is already in CUDA (and the array in device), so it will not have memory transfers from host to device and vice versa.

My problem is: n is not big. Difficultly it will be greater than 8.

I've tried to parallelize it, but my "new" code took more time than the code above.

I was studying reduction and min operations, but i've checked that it's useful when n is big.

So, any tips? Can i parallelize it efficiently, i.e., with a low overhead?

share|improve this question
    
I dont understand what you are asking here. How can "Array have more than one address"? Whyis there a difficulty if "it will be greater than 8"? It isn't clear what you want to do, why what you have done isn't acceptable and what that approach is. –  talonmies Jul 24 '13 at 18:57
    
When you say that array may have more than one address, do you mean that array elements can assume values corresponding to more than one address value? But, regardless to that, you are perhaps answering to your question by yourself: GPU is convenient when large arrays are concerned. Roughly speaking, CPUs are faster than GPUs and, when the arrays are small, you pay too much in the overhead of setting up a kernel launch. So, although you do not provide your approach, with some common sense I would say that I would not be surprised that porting your code wouldn't be worth. –  JackOLantern Jul 24 '13 at 20:42
    
@talonmies, i apologise for my wrong question. I said it was CPU code because the code run in a serialized way, like CPU code. Sorry. I've changed the phrase about the array and addresses. Check if you understand now, the way i've asked was really confused. It's edited now. –  Blufter Jul 25 '13 at 0:42
    
@JackOLantern, i apologise for the way that i've asked my question. I edited it. Now i explain it better. I know, maybe i have answered my question. But this is what i want to know, if there is an optimized algorithm for a small n. Sorry for the way that i've writed my question, it was really confused. –  Blufter Jul 25 '13 at 0:45
1  
@Blufter You could have just updated this question instead of opening another one if it is just a more detailed description of this same problem. –  Christian Rau Jul 30 '13 at 6:54

2 Answers 2

Since you say the array is a shared memory resource, the result of this search is the same for each thread of a block. This means a first and simple optimization would be to only let a single thread do the search. This will free all but the first warp of the block from doing any work (they still need to wait for the result, yet don't have to waste any computing resources):

__shared__ void *result = NULL;
if(tid == 0)
{
    for(unsigned int i=0; i<n; ++i)
    {
        if (array[i] != NULL)
        {
            result = array[i];
            break;
        }
    }
}
__syncthreads();
return result;

A step further would then be to let the threads perform the search in parallel as a classic intra-block reduction. If you can guarantee n to always be <= 64, you can do this in a single warp and don't need any synchronization during the search (except for the complete synchronization at the end, of course).

for(unsigned int i=n/2; i>32; i>>=1)
{
    if(tid < i && !array[tid])
        array[tid] = array[tid+i];
    __syncthreads();
}

if(tid < 32)
{
    if(n > 32 && !array[tid]) array[tid] = array[tid+32];
    if(n > 16 && !array[tid]) array[tid] = array[tid+16];
    if(n > 8 && !array[tid]) array[tid] = array[tid+8];
    if(n > 4 && !array[tid]) array[tid] = array[tid+4];
    if(n > 2 && !array[tid]) array[tid] = array[tid+2];
    if(n > 1 && !array[tid]) array[tid] = array[tid+1];
}

__syncthreads();    
return array[0];

Of course the example assumes n to be a power of two (and the array to be padded with NULLs accordingly), but feel free to tune it to your needs and optimize this further.

share|improve this answer
    
This code is brittle and is likely to fail if the hardware or compiler optimizations change significantly (they have in the past, they will in the future). Plus, for the single warp case you can do it with a single line of code: __ffs(__ballot(array[threadIdx.x] != NULL)) (sm_20 or later). –  harrism Jul 26 '13 at 5:07
    
@harrism Then feel free to downvote it. By the way, if the hardware changes significantly, you have to rework it anyway, GPU code is still far from write once run anywhere, at least if concerned about performance. But feel free to write your own answer using intrinsic stuff I've never heard about. –  Christian Rau Jul 26 '13 at 7:24

Keeping things simple, one of the major limiting factors of GPGPU code is memory management. In most computers copying memory to the device (GPU) is a slow process.

As illustrated by http://www.ncsa.illinois.edu/~kindr/papers/ppac09_paper.pdf:

"The key requirement for obtaining effective acceleration from GPU subroutine libraries is minimization of I/O between the host and the GPU."

This is because I/O operations between host and device are SLOW!

Tying this back to your problem, it doesn't really make sense to run on the GPU since the amount of data you mention is so small. You would spend more time running the memcpy routines than it would take to run on the CPU in the first place - especially since you mention you are only interested in the first match.

One common misconception that many people have is that 'if I run it on the GPU, it has more cores so will run faster' and this just isn't the case.

When deciding if it is worth porting to CUDA or OpenCL you must think about if the process is inherently parallel or not - are you processing very large amounts of data etc.?

share|improve this answer
    
I've edited my question, i said that is was CPU code because it runs serialized, just like CPU. But it is already in GPU, thus i'll not have memory transfers between host and device. But i want to know yet if there is a way to parallelize the "first match search" efficiently for a n small (n < 8). I appreciate your help. –  Blufter Jul 25 '13 at 0:51
    
My point is - for small n there is no point in trying to implement a parallel implementation for it. That's not what the GPU is designed for. If you're only searching for the first match, then the whole thing is inherently a serial process. Even if you could do this in parallel it would surely just over complicate things. n is so small it doesn't seem worth it. That's just my understanding of the situation. –  tjenks Jul 25 '13 at 11:09
    
tjenks, i wrote another question with much more details. I'll appreciate if you read it and answer what your think, if it is woth or not. Thank you: stackoverflow.com/questions/17937438/… –  Blufter Jul 30 '13 at 2:40

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