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I'm trying to run an openmp realization of Dijkstra's algorithm which I downloaded here

If I add for example one more vertice from 5 to 6, so that the path from 0th goes through two vertices, my program fails to give me a correct result, saying that the distance between 0th and 6th is infinite :^( What can be the reason?

#define LARGEINT 2<<30-1  // "infinity"
#define NV 6

// global variables, all shared by all threads by default

int ohd[NV][NV],  // 1-hop distances between vertices
mind[NV],  // min distances found so far
notdone[NV], // vertices not checked yet
nth,  // number of threads
chunk,  // number of vertices handled by each thread
md,  // current min over all threads
mv;  // vertex which achieves that min

void init(int ac, char **av)
{  int i,j;
for (i = 0; i < NV; i++)  
  for (j = 0; j < NV; j++)  {
     if (j == i) ohd[i][i] = 0;
     else ohd[i][j] = LARGEINT;
ohd[0][1] = ohd[1][0] = 40;
ohd[0][2] = ohd[2][0] = 15;
ohd[1][2] = ohd[2][1] = 20;
ohd[1][3] = ohd[3][1] = 10;
ohd[1][4] = ohd[4][1] = 25;
ohd[2][3] = ohd[3][2] = 100;
ohd[1][5] = ohd[5][1] = 6;
ohd[4][5] = ohd[5][4] = 8;
for (i = 1; i < NV; i++)  {
  notdone[i] = 1;
  mind[i] = ohd[0][i];

// finds closest to 0 among notdone, among s through e
void findmymin(int s, int e, int *d, int *v)
{  int i;
  *d = LARGEINT; 
  for (i = s; i <= e; i++)
     if (notdone[i] && mind[i] < *d)  {
        *d = ohd[0][i];
        *v = i;

// for each i in [s,e], ask whether a shorter path to i exists, through
// mv
void updateohd(int s, int e)
{  int i;
   for (i = s; i <= e; i++)
      if (mind[mv] + ohd[mv][i] < mind[i])  
     mind[i] = mind[mv] + ohd[mv][i];

void dowork()
   #pragma omp parallel  // Note 1  
   {  int startv,endv,  // start, end vertices for this thread
      step,  // whole procedure goes NV steps
      mymd,  // min value found by this thread
      mymv,  // vertex which attains that value
      me = omp_get_thread_num();  // my thread number
      #pragma omp single   // Note 2
      {  nth = omp_get_num_threads();  chunk = NV/nth;  
     printf("there are %d threads\n",nth);  }
      // Note 3
      startv = me * chunk; 
      endv = startv + chunk - 1;
      for (step = 0; step < NV; step++)  {
     // find closest vertex to 0 among notdone; each thread finds
     // closest in its group, then we find overall closest
     #pragma omp single 
     {  md = LARGEINT; mv = 0;  }
     // update overall min if mine is smaller
     #pragma omp critical  // Note 4
     {  if (mymd < md)  
          {  md = mymd; mv = mymv;  }
     // mark new vertex as done 
     #pragma omp single 
     {  notdone[mv] = 0;  }
     // now update my section of ohd
     #pragma omp barrier 

int main(int argc, char **argv)
{  int i;
   // back to single thread now
   printf("minimum distances:\n");
   for (i = 1; i < NV; i++)
share|improve this question
up vote 3 down vote accepted

There are two problems here:

If the number of threads doesn't evenly divide the number of values, then this division of work

  startv = me * chunk;
  endv = startv + chunk - 1;

is going to leave the last (NV - nth*(NV/nth)) elements undone, which will mean the distances are left at LARGEINT. This can be fixed any number of ways; the easiest for now is to give all remaining work to the last thread

  if (me == (nth-1)) endv = NV-1;

(This leads to more load imbalance than is necessary, but is a reasonable start to get the code working.)

The other issue is that a barrier has been left out before setting notdone[]

 #pragma omp barrier
 #pragma omp single 
 {  notdone[mv] = 0;  }

This makes sure notdone is updated and updateohd() is started only after everyone has finished their findmymin() and updated md and mv.

Note that it's very easy to introduce errors into the original code you started with; the global variables used make it very difficult to reason about. John Burkardt has a nicer version of this same algorithm for teaching up on his website here, which is almost excessively well commented and easier to trace through.

share|improve this answer
The code you link to is a thing of documentative beauty. – Richard Nov 18 '12 at 17:32

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