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I'm busy working on a LS method, I manually implemented a conjugate gradient solver, but after updating my CUDA version, I saw that there is a new function (cusolverDnSSgels) which I assume is faster than my manual implementation. My first task was to try and run it on a test case (see below), I'd expect the result to be: -6.5, 9.7 according to MATlab. Unfortunately I cannot find what I did wrong, I also cannot find an example because it is a relatively new function.

The output says that niter= -3, which would suggest too many iterations according to the documentation, however this would not make sense, as it is a very small matrix which should be easily solvable.

#include <iostream>
#include <cuda_runtime.h>
#include <cublas_v2.h>
#include <cusolverDn.h>
#include "device_launch_parameters.h"


int main()
{   
    //init id, handle and stat
    int id = cudaGetDevice(&id);
    cusolverDnHandle_t cusolverH;
    cusolverStatus_t stat;

    // create handle
    stat = cusolverDnCreate(&cusolverH);

    //params
    const int C = 3;
    const int M = 2;
    long lda = C;

    //init variables
    float *Amat, *Ymat, *Xmat;
    float *gAmat, *gYmat, *gXmat;

    //allocate mem
    Amat = (float*)malloc(M * C * sizeof(float));
    Ymat = (float*)malloc(C * sizeof(float));
    Xmat = (float*)malloc(M * sizeof(float));

    srand(100);
#if 0
    for (int i = 0; i < C * M; i++) {
        Amat[i] = rand() % 10 + 1;
        Amat[i] = (float)Amat[i];

    }

    for (int i = 0; i < C; i++) {
        Ymat[i] = rand() % 10 + 1;
        Ymat[i] = (float)Ymat[i];
    }
#endif
    Amat[0] = 6;
    Amat[1] = 7;
    Amat[2] = 6;
    Amat[3] = 5;
    Amat[4] = 5;
    Amat[5] = 5;
    Ymat[0] = 9;
    Ymat[1] = 3;
    Ymat[2] = 10;

    //allocate mem
    cudaMalloc(&gAmat, M * C * sizeof(float));
    cudaMalloc(&gYmat, C * sizeof(float));
    cudaMalloc(&gXmat, M * 1 * sizeof(float));

    //copy mem
    cudaMemcpy(gAmat, Amat, M * C * sizeof(float), cudaMemcpyHostToDevice);
    cudaMemcpy(gYmat, Ymat, C * 1 * sizeof(float), cudaMemcpyHostToDevice);

    float *gdwork;
    size_t work_bytes;

    stat = cusolverDnSSgels_bufferSize(cusolverH,C, M, 1, gAmat, lda, gYmat, C, gXmat, M, NULL, &work_bytes);

    std::cout << "Status = " << stat << std::endl;

    int niter = 0;
    int dinfo = 0;

    cudaMalloc(&gdwork, work_bytes * sizeof(float));

    stat = cusolverDnSSgels(cusolverH, C, M, 1, gAmat, lda, gYmat, C, gXmat, M, gdwork, work_bytes, &niter, &dinfo);

    std::cout << "Status = " << stat  << std::endl;
    std::cout << "niter = "  << niter << std::endl;
    std::cout << "dinfo = "  << dinfo << std::endl;

    cudaDeviceSynchronize();

    cudaMemcpy(Xmat, gXmat, M * 1 * sizeof(float), cudaMemcpyDeviceToHost);


    //Output printed
    std::cout << Xmat[0] << ", " << Xmat[1] << std::endl;

    //free memory
    cudaFree(gdwork);
    free(Amat);
    free(Ymat);
    free(Xmat);


    cudaFree(gXmat);
    cudaFree(gAmat);
    cudaFree(gYmat);

    //destory handle
    cusolverDnDestroy(cusolverH);



    return 0;
}

The results I get are:

Status = 0
Status = 0
niter = -3
dinfo = 0
-4.31602e+08, -4.31602e+08

Could someone point out what I am doing wrong?

1 Answer 1

2

You have a problem with your dinfo parameter usage. Referring to the documentation, we see that:

Parameters of cusolverDngels() functions

parameter Memory In/out Meaning

dinfo device output Status of the IRS solver on the return. If 0 - solve was successful. If dinfo = -i then i-th argument is not valid.

the dinfo parameter is expected to live in device memory. But you have it in host memory:

int dinfo = 0;

If I move the storage to the proper location, your code outputs the values you indicate as expected:

$ cat t143.cu
#include <iostream>
#include <cublas_v2.h>
#include <cusolverDn.h>


int main()
{
    //init id, handle and stat
    int id = cudaGetDevice(&id);
    cusolverDnHandle_t cusolverH;
    cusolverStatus_t stat;

    // create handle
    stat = cusolverDnCreate(&cusolverH);

    //params
    const int C = 3;
    const int M = 2;
    long lda = C;

    //init variables
    float *Amat, *Ymat, *Xmat;
    float *gAmat, *gYmat, *gXmat;

    //allocate mem
    Amat = (float*)malloc(M * C * sizeof(float));
    Ymat = (float*)malloc(C * sizeof(float));
    Xmat = (float*)malloc(M * sizeof(float));

    srand(100);
#if 0
    for (int i = 0; i < C * M; i++) {
        Amat[i] = rand() % 10 + 1;
        Amat[i] = (float)Amat[i];

    }

    for (int i = 0; i < C; i++) {
        Ymat[i] = rand() % 10 + 1;
        Ymat[i] = (float)Ymat[i];
    }
#endif
    Amat[0] = 6;
    Amat[1] = 7;
    Amat[2] = 6;
    Amat[3] = 5;
    Amat[4] = 5;
    Amat[5] = 5;
    Ymat[0] = 9;
    Ymat[1] = 3;
    Ymat[2] = 10;

    //allocate mem
    cudaMalloc(&gAmat, M * C * sizeof(float));
    cudaMalloc(&gYmat, C * sizeof(float));
    cudaMalloc(&gXmat, M * 1 * sizeof(float));

    //copy mem
    cudaMemcpy(gAmat, Amat, M * C * sizeof(float), cudaMemcpyHostToDevice);
    cudaMemcpy(gYmat, Ymat, C * 1 * sizeof(float), cudaMemcpyHostToDevice);

    float *gdwork;
    size_t work_bytes;

    stat = cusolverDnSSgels_bufferSize(cusolverH,C, M, 1, gAmat, lda, gYmat, C, gXmat, M, NULL, &work_bytes);

    std::cout << "Status = " << stat << std::endl;

    int niter = 0;
    int *dinfo, hinfo;

    cudaMalloc(&gdwork, work_bytes * sizeof(float));
    cudaMalloc(&dinfo, sizeof(int));

    stat = cusolverDnSSgels(cusolverH, C, M, 1, gAmat, lda, gYmat, C, gXmat, M, gdwork, work_bytes, &niter, dinfo);
    cudaMemcpy(&hinfo, dinfo, sizeof(int), cudaMemcpyDeviceToHost);
    std::cout << "Status = " << stat  << std::endl;
    std::cout << "niter = "  << niter << std::endl;
    std::cout << "dinfo = "  << hinfo << std::endl;

    cudaDeviceSynchronize();

    cudaMemcpy(Xmat, gXmat, M * 1 * sizeof(float), cudaMemcpyDeviceToHost);


    //Output printed
    std::cout << Xmat[0] << ", " << Xmat[1] << std::endl;

    //free memory
    cudaFree(gdwork);
    free(Amat);
    free(Ymat);
    free(Xmat);


    cudaFree(gXmat);
    cudaFree(gAmat);
    cudaFree(gYmat);

    //destory handle
    cusolverDnDestroy(cusolverH);



    return 0;
}
$ nvcc -o t143 t143.cu -lcublas -lcusolver
$ cuda-memcheck ./t143
========= CUDA-MEMCHECK
Status = 0
Status = 0
niter = -51
dinfo = 0
-6.5, 9.7
========= ERROR SUMMARY: 0 errors
$

Notes:

  • I am using CUDA 11.3 for the above. If you are using an earlier version, I strongly recommend you move forward to CUDA 11.3 or newer for usage of this function.

  • You can get a hint as to the problem by running your code with cuda-memcheck

  • It was fairly quick to spot the problem by reviewing your parameter usage with the table of parameter locations (host/device) given in the documentation. You had a problem here which was similar in that you could focus in on the problem by reviewing your parameter locations (host/device) against the table given in the documentation. This may be a good thing to check to save yourself time in the future.

1
  • Thank you very much. You are right, I should look at them better, I'm still fairly new, so sometimes I just read over these things, or I think that the mistake is somewhere else. Anyway, thanks!!
    – Taliebram
    May 18, 2021 at 7:14

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