Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

Next program is going to inverse a matrix on GF(2^8)(addition is similar to XOR,multiplication applys table loop-up method) using Gauss-Jordan elimination on NVIDIA GeForce 310 GPU,CUDA v4.2.

typedef unsigned char BYTE;
#define BLOCK_SIZE 16

// addition
__inline __device__ BYTE  
add_GF(BYTE a,BYTE b)
{
    return a^b;
}

// subtraction
__inline __device__ BYTE  
sub_GF(BYTE a,BYTE b)   
{
    return a^b;
}

// multiplication
__inline __device__ BYTE  
mul_GF(BYTE a,BYTE b,BYTE *d_numOf, BYTE *d_indexOf )    
{
    if(a==0 || b == 0) return 0;
    return d_numOf[(d_indexOf[a] + d_indexOf[b])%255];

}

// divison
__inline __device__ BYTE
div_GF(BYTE a,BYTE b, BYTE *d_numOf,BYTE *d_indexOf, BYTE *d_inv)
{
    if(b == 0) return 0;
    return mul_GF(a,d_inv[b],d_numOf,d_indexOf);
}

// swap two line
__global__ void
LineSwap(BYTE *M, int *n,int *a, int *b)
{
    BYTE temp;
    const unsigned int tid = blockIdx.x*blockDim.x+threadIdx.x;

    temp = M[(*a)*(*n+*n)+tid];
    M[*a*(*n+*n)+tid] = M[(*b)*(*n+*n)+tid];
    M[*b*(*n+*n)+tid] = temp;

}

// multiply a line by a factor
__global__ void
LineMul(BYTE *M, int *n,int *a, BYTE *d_numOf, BYTE *d_indexOf, BYTE *d_inv)
{
    BYTE k =  div_GF(128, M[*a*(*n+*n)+*a], d_numOf, d_indexOf, d_inv);
    const unsigned int tid = blockIdx.x*blockDim.x+threadIdx.x;

    M[*a*(*n+*n)+tid] = mul_GF( k , M[*a*(*n+*n)+tid], d_numOf, d_indexOf );
}

// multiply a line by a factor then subtract another line
__global__ void
LineMulSub(BYTE *M, int *n,int *a, BYTE *k, int *b, BYTE *d_numOf, BYTE *d_indexOf)
{
    const unsigned int tid = blockIdx.x*blockDim.x+threadIdx.x;

    M[*b*(*n+*n)+tid] = sub_GF( M[*b*(*n+*n)+tid] , mul_GF(*k ,M[*a*(*n+*n)+tid], d_numOf, d_indexOf));
}

// compute the inverse matrix 
bool InvMatGF(BYTE* h_A, BYTE* &h_Inv, int n)
{
    //h_M[n*(n+n)] is a augmented matrix.
    BYTE *h_M = new BYTE [n*(n+n)];
    for(int i=0; i < n*(n+n); i++)
    {
        h_M[i] = 0;
    }

    for( int i=0; i<n; i++ )
    {
        for( int j=0; j<n; j++ )
        {
            h_M[i*(n+n)+j] = h_A[i*n+j];
            h_M[i*(n+n)+(n+j)] = 0;
        }
    }

    for( int i=0; i<n; i++ )
    {
        h_M[i*(n+n)+(n+i)] = 128;
    }

    BYTE *d_A = NULL;
    BYTE *d_M = NULL;
    int *d_n = NULL;
    int *d_i = NULL;
    int *d_j = NULL;
    BYTE *d_numOf = NULL;
    BYTE *d_indexOf = NULL;
    BYTE *d_inv = NULL;

    int size_A = n*n*sizeof(BYTE);
    int size_M = n*(n+n)*sizeof(BYTE);
    int size_Lookup_Table = TABLE_SIZE*sizeof(BYTE);
    int size_INTEGER = sizeof(int);

    checkCudaErrors( cudaMalloc((void**) &d_A, size_A) );
    checkCudaErrors( cudaMalloc((void**) &d_M, size_M));
    checkCudaErrors( cudaMalloc((void**) &d_n, size_INTEGER) );
    checkCudaErrors( cudaMalloc((void**) &d_i, size_INTEGER) );
    checkCudaErrors( cudaMalloc((void**) &d_j, size_INTEGER) );
    checkCudaErrors( cudaMalloc((void**) &d_numOf, size_Lookup_Table) );
    checkCudaErrors( cudaMalloc((void**) &d_indexOf, size_Lookup_Table) );
    checkCudaErrors( cudaMalloc((void**) &d_inv, size_Lookup_Table) );

    checkCudaErrors( cudaMemcpy(d_A,h_A,size_A,cudaMemcpyHostToDevice) );
    checkCudaErrors( cudaMemcpy(d_n,&n,size_INTEGER,cudaMemcpyHostToDevice) );
    checkCudaErrors( cudaMemcpy(d_numOf,&numOf,size_Lookup_Table,cudaMemcpyHostToDevice) );
    checkCudaErrors( cudaMemcpy(d_indexOf,&indexOf,size_Lookup_Table,cudaMemcpyHostToDevice) );
    checkCudaErrors( cudaMemcpy(d_inv,&inv,size_Lookup_Table,cudaMemcpyHostToDevice) );

    dim3 blockDim(BLOCK_SIZE,BLOCK_SIZE,1);
    dim3 gridDim(((n+n)+blockDim.x-1)/blockDim.x,1,1);

    cudaEvent_t start,stop;
    cudaEventCreate( &start );
    cudaEventCreate( &stop );
    cudaEventRecord( start, 0 );

    for(int i = 0; i < n; i++)
    {
        if(h_M[i*(n+n)+i] != 0)
        {
            checkCudaErrors(cudaMemcpy(d_i, &i, sizeof(int), cudaMemcpyHostToDevice));
            checkCudaErrors( cudaMemcpy(d_M,h_M,size_M,cudaMemcpyHostToDevice) );
            LineMul<<<gridDim,blockDim,0>>>(d_M,d_n,d_i,d_numOf,d_indexOf,d_inv); // on GPU
            checkCudaErrors( cudaMemcpy(h_M,d_M,size_M,cudaMemcpyDeviceToHost) );

            for(int j = 0; j < n; j++)
            {
                if(j != i)
                {
                    BYTE *d_MElem = 0;

                    checkCudaErrors( cudaMalloc((void**) &d_MElem,sizeof(BYTE)) );
                    checkCudaErrors( cudaMemcpy(d_j, &j, sizeof(int), cudaMemcpyHostToDevice) );
                    checkCudaErrors( cudaMemcpy(d_MElem,&h_M[j*(n+n)+i],sizeof(BYTE),cudaMemcpyHostToDevice) );
                    LineMulSub<<<gridDim,blockDim,0>>>(d_M,d_n,d_i,d_MElem,d_j,d_numOf,d_indexOf);// on GPU
                    checkCudaErrors( cudaMemcpy(h_M,d_M,size_M,cudaMemcpyDeviceToHost) );
                    checkCudaErrors( cudaFree(d_MElem) );
                }
            }
        }
        else
        {
            for(int j = i+1; j < n; j++)
            {
                if(h_M[j*(n+n)+i] != 0)
                {
                    checkCudaErrors(cudaMemcpy(d_i, &i, sizeof(int), cudaMemcpyHostToDevice));
                    checkCudaErrors(cudaMemcpy(d_j, &j, sizeof(int), cudaMemcpyHostToDevice));
                    checkCudaErrors( cudaMemcpy(d_M,h_M,size_M,cudaMemcpyHostToDevice) );
                    LineSwap<<<gridDim,blockDim,0>>>(d_M,d_n,d_i,d_j);//on GPU
                    checkCudaErrors( cudaMemcpy(h_M,d_M,size_M,cudaMemcpyDeviceToHost) );
                    i--;
                    break;
                }
                if(j == n-1)
                {
                    printf("(1)No inverse matrix!\n");
                    return false;
                }
            }
        }
    }

    for (int i = 0; i < n; i++)
    {
            if(h_M[i*(n+n)+i] != 128)
        {
            printf("(2)No inverse matrix: not full rank!\n");
            return false;
        }
    }

    for (int i = 0; i < n; i++)
    {
        for (int j = 0; j < n; j++)
        {
            h_Inv[i*n+j] =  h_M[i*(n+n)+n+j];
        }
    }

    cudaEventRecord( stop, 0 );// united on "ms"
    cudaEventSynchronize( stop );
    float elapsedTime;
    cudaEventElapsedTime( &elapsedTime, start, stop );
    cudaEventDestroy( start );
    cudaEventDestroy( stop );

    float throughputInverse = (float) n/(elapsedTime*0.001) *0.000001;
    printf("%d\t%f\t%f\t",n,elapsedTime*0.001,throughputInverse);

    checkCudaErrors( cudaFree(d_i) );
    checkCudaErrors( cudaFree(d_j) );
    checkCudaErrors( cudaFree(d_A) );
    checkCudaErrors( cudaFree(d_M) );
    checkCudaErrors( cudaFree(d_n) );
    checkCudaErrors( cudaFree(d_numOf) );
    checkCudaErrors( cudaFree(d_indexOf) );
    checkCudaErrors( cudaFree(d_inv) );
    delete[] h_M;

    return true;
}

But question is when I compile it by

nvcc -g -G INVonGPUv1.1.cu -o INVonGPUv1.1 -I../../NVIDIA_GPU_Computing_SDK/C/common/inc -I../../NVIDIA_GPU_Computing_SDK/shared/inc  -arch=compute_12

,a normal output is right as follow.

################### Inversing start ####################
#n  timeInverse(s)  throughputInverse(MB/s) errorRate(0~1)  isInverse
#=================== INVERSE on GPU v1.0 ====================
128 1.565791    0.000082    1
256 14.190008   0.000018    1
512 154.687016  0.000003    1
################ Inversing stop ####################

But when I remove "-g -G" and complie with

nvcc INVonGPUv1.1.cu -o INVonGPUv1.1 -I../../NVIDIA_GPU_Computing_SDK/C/common/inc -I../../NVIDIA_GPU_Computing_SDK/shared/inc  -arch=compute_12

,I couldn't get the inverse matrix.Why and what the working principle of "-g -G"?

################### Inversing start ####################
#n  timeInverse(s)  throughputInverse(MB/s) errorRate(0~1)  isInverse
#=================== INVERSE on GPU v1.0 ====================
(1)No inverse matrix!
0
(1)No inverse matrix!
0
(1)No inverse matrix!
0
################ Inversing stop ####################

Thanks in advance!

share|improve this question
1  
It seems appropriate to point out that you haven't posted any of your kernel (device) code. –  Robert Crovella Apr 30 '13 at 4:28
    
First step is to run the code with cuda-memcheck. There is almost certainly an out of bounds memory access in one of your kernel calls (that you haven't shown) and they fail when compiled with optimisation and pass when compiled for debugging, –  talonmies Apr 30 '13 at 6:07

1 Answer 1

up vote 0 down vote accepted

-g is similar to that option in gcc: it produces debug information for host code.

-G produces debug information for device code.

For more information on command options to NVCC see the manual on NVCC. This PDF should be installed along with CUDA Toolkit.

Your code sample is a bit too long to dissect. Go over your code carefully. Bugs that appear in release build and not in debug mode and vice versa are pretty common. They are usually due to some memory bug in the code that manifests in one mode and not in the other.

share|improve this answer
    
-G also eliminates a number of optimizations that the device code compiler may make, which is probably why the difference in behavior is observed. The device code generated with -G is usually quite a bit different than the device code without -G, due to optimizations made by the compiler. –  Robert Crovella Apr 30 '13 at 3:52
    
Thank @RobertCrovella, @talonmies and @Ashwin! My mistake is dim3 blockDim(BLOCK_SIZE,BLOCK_SIZE,1);. When I change it to dim3 blockDim(BLOCK_SIZE,1,1);, the result is right as compiled with "-G". I think the mistake is memory access error.Thanks very much! –  liwang Apr 30 '13 at 11:23
    
@liwang There you go! Just as I suspected :-) –  Ashwin May 1 '13 at 2:31

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.