# Dijkstra's algorithm openmp strange behavior

I'm trying to run an openmp realization of Dijkstra's algorithm which I downloaded here heather.cs.ucdavis.edu/~matloff/OpenMP/Dijkstra.c

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
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
#pragma omp single   // Note 2
{  nth = omp_get_num_threads();  chunk = NV/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;  }
findmymin(startv,endv,&mymd,&mymv);
// 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
updateohd(startv,endv);
#pragma omp barrier
}
}
}

int main(int argc, char **argv)
{  int i;
init(argc,argv);
dowork();
// back to single thread now
printf("minimum distances:\n");
for (i = 1; i < NV; i++)
printf("%d\n",mind[i]);
}
``````
-

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.

-
The code you link to is a thing of documentative beauty. –  Richard Nov 18 '12 at 17:32