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I'm making a test on a BFS algorithm on CUDA ( wich I know that has some syncronization problems, but it's part of my work to test it anyway ) but i'm having problems on using (or creating?) 1M+ size graphs.

Here's the code I use to create them:

#include <stdio.h>
#include <stdlib.h>
#include <time.h>


#define GRAPHSIZE 1000000

struct Node 
{
    int begin;     // comeco da sub-string de vizinhos
    int num;    // tamanho da sub-string de vizinhos
};



int getSize()
{
int size,arcs;

    printf("Size of the graph: \nNodes:\n>>");
    scanf ("%d", &size);

return size;
}



void createEdges(int graphSize, int* Edges)
{

int j,value, aux, rndIdx;

int edgesSize = 2*GRAPHSIZE;

srand(time(NULL));



printf ("\nGS : %d\n", graphSize);

j = 1;

    for (int i=0; i < edgesSize; i++) //first it creates an ordered array of edges
    {

        if (j < GRAPHSIZE)
        {
        Edges [i] = j;
        j++;
        }
            else
            {
            j=1;        
            Edges [i] = j; 
            j++;
            }

    }



    for (int i=0; i < edgesSize; i++) //now, it randomly swaps the edges array
    {

    rndIdx = rand()%graphSize;

    aux = Edges[rndIdx];
    Edges[rndIdx] = Edges [i];
    Edges [i] = aux;

    }

} 


int main ()
{

int size,graphAtts[2];

int edgesSize = 2*GRAPHSIZE;

int Edges[edgesSize];

struct Node node[GRAPHSIZE];

FILE *file;



printf("____________________________\nRandom graph generator in compact format, optmized for CUDA algorithms by Ianuarivs Severvs.\nFor details about this format read the README. \n");

//size = getSize(graphAtts);

//printf ("%d,%d",size,arcs);

createEdges(GRAPHSIZE,Edges); // or size?

/*
    for (int i = 0; i < edgesSize ; i ++)
    {
    printf ("-- %d --", Edges[i]);
    }   

*/

printf("\nEdges:\n");
for (int i=0; i < edgesSize; i++) 
printf("%d,",Edges[i]);


    for (int i=0,j=0 ; i < GRAPHSIZE; i++,j+=2) // now, completes the graph
    {
    node[i].begin=j;
    node[i].num=2;
    printf ("\n node %d : begin = %d, num = 2",i,j); 
    }

printf("\n");

//writes file:
file = fopen ("graph1M.g","wb");
fwrite (&Edges, edgesSize * sizeof(int),1,file);
fwrite (&node, GRAPHSIZE * sizeof(struct Node),1,file);
fclose(file);


    for (int i = 0; i < edgesSize ; i ++)
    {
    printf ("-- %d --", Edges[i]);
    }   


    for (int i = 0; i < GRAPHSIZE ; i ++)
    {
    printf ("* %d *", i);
    }


}

And here's my BFS code (on CUDA):

#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <cuda.h>
#include <cutil.h> 

#define GRAPHSIZE 1000000

struct Node 
{
    int begin;     // begining of the substring
    int num;    // size of the sub-string 
};

__global__ void BFS (Node *Va, int *Ea, bool *Fa, bool *Xa, int *Ca, bool *parada) // memory races on both Xa and Ca
{

    int tid = threadIdx.x + blockIdx.x * blockDim.x;
    if (tid > GRAPHSIZE)
           *parada=true;


        if (Fa[tid] == true && Xa[tid] == false)
        {
        Fa[tid] = false; 
        Xa[tid] = true;
        //__syncthreads(); // this solves the memrace problem as long as the threads are all on the same block
                   for (int i = Va[tid].begin;  i < (Va[tid].begin + Va[tid].num); i++) // Va begin is where it's edges' subarray begins, Va is it's                                                                        number of elements
            {             
                int nid = Ea[i];

                if (Xa[nid] == false)
                {
                Ca[nid] = Ca[tid] + 1;               
                Fa[nid] = true;             
                *parada = true;
                }

            }                   

        }

}

// The BFS frontier corresponds to all the nodes being processed at the current level.


int main()
{

    // for the time couting:
    cudaEvent_t start, stop;
    float time;
    cudaEventCreate(&start);
    cudaEventCreate(&stop);


    FILE * file;

    printf("\nLoading graph file...\n");


    struct Node node[GRAPHSIZE];
    int edgesSize = 2*GRAPHSIZE;
    int edges[edgesSize];


    file = fopen ("graph1M.g","rb");
    printf("abriu");    
    fread (&edges, edgesSize * sizeof(int),1,file);
    fread (&node, GRAPHSIZE * sizeof(struct Node),1,file);
    fclose(file);

 //For file read test propouses only:

/*
    for (int i = 0; i < edgesSize ; i ++)
    {
    printf ("-- %d --", edges[i]);
    }   


    for (int i = 0; i < GRAPHSIZE ; i ++)
    {
    printf ("* %d *", i);
    }
*/  



    bool frontier[GRAPHSIZE]={false}; 
    bool visited[GRAPHSIZE]={false}; 
    int custo[GRAPHSIZE]={0}; 

    int source=0; 
    frontier[source]=true; 

    Node* Va; 
    cudaMalloc((void**)&Va,sizeof(Node)*GRAPHSIZE); 
    cudaMemcpy(Va,node,sizeof(Node)*GRAPHSIZE,cudaMemcpyHostToDevice); 

    int* Ea; 
    cudaMalloc((void**)&Ea,sizeof(Node)*GRAPHSIZE); 
    cudaMemcpy(Ea,edges,sizeof(Node)*GRAPHSIZE,cudaMemcpyHostToDevice); 

    bool* Fa; 
    cudaMalloc((void**)&Fa,sizeof(bool)*GRAPHSIZE); 
    cudaMemcpy(Fa,frontier,sizeof(bool)*GRAPHSIZE,cudaMemcpyHostToDevice); 

    bool* Xa; 
    cudaMalloc((void**)&Xa,sizeof(bool)*GRAPHSIZE); 
    cudaMemcpy(Xa,visited,sizeof(bool)*GRAPHSIZE,cudaMemcpyHostToDevice); 

    int* Ca; 
    cudaMalloc((void**)&Ca,sizeof(int)*GRAPHSIZE); 
    cudaMemcpy(Ca,custo,sizeof(int)*GRAPHSIZE,cudaMemcpyHostToDevice); 


    dim3 grid(100,100,1); //blocks per grid
    dim3 threads(100,1,1);  // threads per block




    bool para; 
    bool* parada; 
    cudaMalloc((void**)&parada,sizeof(bool)); 
    printf("_____________________________________________\n");
    int count=0;

    cudaEventRecord(start, 0);
    do{ 
        count ++;
        para=false; 
        cudaMemcpy(parada,&para,sizeof(bool),cudaMemcpyHostToDevice);       
        BFS <<<grid,threads,0>>>(Va,Ea,Fa,Xa,Ca,parada);    
        CUT_CHECK_ERROR("kernel1 execution failed"); 
        cudaMemcpy(&para,parada,sizeof(bool),cudaMemcpyDeviceToHost); 


    }while(para); 

    cudaEventRecord(stop, 0);
    cudaEventSynchronize(stop);


    //printf("\nFinal:\n");
    cudaMemcpy(custo,Ca,sizeof(int)*GRAPHSIZE,cudaMemcpyDeviceToHost); 
 /*
    printf("\n_____________________________________________\n");
    for(int i=0;i<GRAPHSIZE;i++) 
        printf("%d  ",custo[i]); 
    printf("\n");

    printf("_____________________________________________\n");
*/

    cudaEventElapsedTime(&time, start, stop);
    printf ("\nTime for the kernel: %lf s \n", time/1000);
    printf ("Number of kernel calls : %d \n", count);


    file = fopen ("graph125MPar","w");


    for(int i=0;i<GRAPHSIZE;i++) 
        fprintf(file,"%d    ",custo[i]); 
    fprintf(file,"\n");
    fclose(file);



}

I'm having a segmantation fault while trying to run it for 1M+ graphs (please note that I used the changed the stack size of the sistem with the command ' ulimit -s 16384 ' on linux)

Can someone help?

share|improve this question

1 Answer 1

up vote 2 down vote accepted

Don't use statically allocated host arrays for the graph, use dynamic memory allocation instead. Your ulimit command is setting the stacksize to 16384 kb, but you require something like 5*sizeof(int) + 2*sizeof(bool) per graph entry which is probably 22 bytes per entry. It is pretty easy to see where you will run out of stack space with 1 million entries.

share|improve this answer
    
Yeah, I was running away from that solution (it's a harder implementation) but I think that'll be the only way out of the bugs –  Imperian Nov 7 '11 at 21:48
    
How is it a harder implementation? You have to change exactly three lines in you current code, and perhaps add three lines to deallocate the storage afterwards, and you are done. –  talonmies Nov 8 '11 at 6:46
    
My point is that handlig with pointers, mainly in parallel algorthms are usually a headache for me.. –  Imperian Nov 8 '11 at 11:31

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