# Different behaviour between scalar and parallel code

I'm wondering why the following code produces different results in its scalar and parallel variants:

``````#define N 10
double P[N][N];
// zero the matrix just to be sure...
for (int i=0; i<N; i++)
for(int j=0; j<N; j++)
P[i][j]=0.0;

double xmin=-5.0,ymin=-5.0,xmax=5.0,ymax=5.0;
double x=xmin,y=ymin;
double step= abs(xmax-xmin)/(double)(N - 1 );
for (int i=0; i<N; i++)
{
#pragma omp parallel for ordered schedule(dynamic)
for ( int j=0; j<N; j++)
{
x = i*step+xmin;
y = j*step+ymin;
P[i][j]=x+y;
}
}
``````

This code produces not completely equal results in its two version (the scalar version has just the `#pragma ...` part commented out). What I've noticed is that a very small percentual of the elements of `P[i][j]` in the parallel version are different from those of the scalar version, but I'm wondering why...

Putting the `#pragma` on the outer loop as suggested is mess...completely wrong results.

P.S. g++-4.4, intel i7, linux

-

Ah, now I can see the problem. Your comment on the last question didn't have enough context for me to see it. But now it's clear.

The problem is here:

``````    x = i*step+xmin;
y = j*step+ymin;
``````

`x` and `y` are declared outside the parallel region, so they are being shared among all the threads. (and thus a nasty race condition among all the threads...)

To fix it, make them local:

``````for ( int j=0; j<N; j++)
{
double x = i*step+xmin;
double y = j*step+ymin;
P[i][j]=x+y;
}
``````

With this fix, you should be able to put the `#pragma` on the outer loop instead of the inner loop.

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yeah, fixed! Now it works with the `#pragma ` in the outer loop! Thank you! –  linello Dec 1 '11 at 11:35
There is also a second possibility to reassure that x,y is thread local. You can use the `private` or `firstprivate` keyword in the pragma: `#pragma omp parallel for ordered schedule(dynamic) private(x,y)` –  Bort Dec 1 '11 at 13:26
@linello, think this answer deserves the green tick! –  Walter Dec 3 '11 at 15:13