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I am dealing with some slowness issues regarding my Monte Carlo simulation that I have developed in CUDA. I have observed very poor performances with my GTX 680 (compute capability 3.0) and I don’t know what is wrong in my way of implementing a Monte Carlo simulation. I tried to ‘unroll’ my loop by doing several paths within my main loop without observing any significant improvements.

I have defined my kernel as following: SimulationVolInterp = parallel.gpu.CUDAKernel('sh_cuda_MC.ptx', 'sh_cuda_MC.cu', 'MCSharedMemory'); SimulationVolInterp.ThreadBlockSize = 2^9; SimulationVolInterp.GridSize = 2^5;

Here is my kernel function :

__global__ void MC(double* vol_int, double* matrice,const double* randomWalk, int nbreSimulation, int nPaths, double S0, double strike, double T, double drift,  const double* strikes_vec, const double* volatility_mat, int l_strikes_vec) {

    //double mydt = (index - nbreSimulation)/nbreSimulation*dt + dt;
    double dt = T/nPaths;
    unsigned int tid = threadIdx.x + blockDim.x * blockIdx.x; 
   // unsigned int stride = blockDim.x*gridDim.x;
    unsigned int index = tid;   
    int workingCol = 0; 
    unsigned int previousMove;  
    if (index < nbreSimulation) {
        matrice[index] = S0;  
        for (workingCol=1; workingCol< nPaths; workingCol++) {
            previousMove = index; 
            index += nbreSimulation;
            vol_int[index] = 0.25;
            matrice[index] = matrice[previousMove]*exp((drift - vol_int[index] *vol_int[index] *0.5)*dt + randomWalk[index]*vol_int[index] *sqrt(dt));

For example, 2^12 simulations x 2^11 steps takes 7 sec, it is quite huge right?! My classic Monte Carlo on Matlab takes less than one sec…

Could someone help me on this point?

Many thanks

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Can't you just initialize vol_int to 0.25 (and not even using an array)? I think it might have a better result. –  Soroosh Bateni Mar 18 '13 at 16:18
Also this way of computing is highly dependent on the previous steps, so try to think about a trade-off here, if you are splitting your calculations in big pieces, you are sacrificing your performance since GPU clock is a lot less than the CPU clock. You have to have a massively parallel algorithm and your instructions should be simple, I don't think assigning 2^11 steps to a single thread is a good idea. –  Soroosh Bateni Mar 18 '13 at 16:54
Thank you for your answers. Actually, I have simplied my code (constant volatility) but I compute a new volatility at each step. Actually I dont really know how to proceed to split the job per thread. In my opinion, the 2^11 steps have to be performed by one single thread in order to avoid concurrent access right? All the examples I have seen about Monte Carlo simulation in CUDA do the same thing : A thread compute all the steps for one simulation. –  ALFRAM Mar 19 '13 at 8:28
Yes your code is highly dependent on its previous steps, I don't see any way to split it further either, but imagine that a single thread has to do 2^11 steps! of course a CPU can do this faster, but also there are 2^12 of them which in this case can run concurrently, apparently for your hardware at least, this trade-off doesn't add up. –  Soroosh Bateni Mar 19 '13 at 9:54
That's annoying :/ I dont really know how to proceed. Even on 2^6 steps, my program is slower than the CPU code (2^7 threads). I dont see what is wrong in my algorithm/ implementation. I should be able to beat the CPU. :/ –  ALFRAM Mar 19 '13 at 13:25

3 Answers 3

up vote 0 down vote accepted

If I want to use C, I have to use a mex file right? I think that mex files are a little bit deprecated since it is possible to simply use feval or arrayfun to execute CUDA code. Regarding the Gather function, you are right, it takes too much time to send the GPU data to the matlab world. Do you know if there is a way to optimize this part of the process. Do you think that using mex file could speed up the gathering of GPU data? Many thanks Soroosh Bateni

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The performance of double precision arithmetic on the GTX 680 is NOT that great. I recall at GTC 2012 a Nvidia engineer advised me that the GTX 680 has a lot less double precision FPU's that single precision FPU's. The card was optimized for gaming not compute.

This bog post http://blog.accelereyes.com/blog/2012/04/26/benchmarking-kepler-gtx-680/ confirms the anecdotal evidence. Try the new GTX Titan card or try the Monte Carlo simulation in single precision ( I suspect neither of these options are very satisfactory for you).

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replace double to float. Double good work, only cuda 3.5

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