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

  • 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

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).


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

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