I have a problem that is driving me mad with OpenCL. I have narrowed down the problem to a specific piece of code that gives me the issue and I quote it below. The problem is that when I execute this code with OpenCL and in serial and compare the results they are not the same. Here the only thing that is an argument to the kernel is the cells variable.

During testing I tried to set the values in the last loop with a specific value which is calculated earlier (e.g. local_density). Then the results I got were correct. From what I understand the problem lies in the u and d_equ arrays when they are used in the loop for calculations. I have to mention that those arrays are of type double and I have added the required pragma to enable double precision.

Is there any need for synchronization or something similar in this code as it is to work for OpenCL?

```
local_density = 0.0;
for(kk = 0; kk < 9; kk++)
{
local_density += tmp_cells[pos].speeds[kk];
}
u_x = (tmp_cells[pos].speeds[1] + tmp_cells[pos].speeds[5] +
tmp_cells[pos].speeds[8] - ( tmp_cells[pos].speeds[3] +
tmp_cells[pos].speeds[6] + tmp_cells[pos].speeds[7]))
/ local_density;
u_y = (tmp_cells[pos].speeds[2] + tmp_cells[pos].speeds[5] +
tmp_cells[pos].speeds[6] - ( tmp_cells[pos].speeds[4] +
tmp_cells[pos].speeds[7] + tmp_cells[pos].speeds[8]))
/ local_density;
u_sq = u_x * u_x + u_y * u_y;
u[1] = u_x ;
u[2] = u_y;
u[3] = - u_x ;
u[4] = - u_y;
u[5] = u_x + u_y;
u[6] = - u_x + u_y;
u[7] = - u_x - u_y;
u[8] = u_x - u_y;
t1 = 2.0 * c_sq;
d_equ[0] = w0 * local_density * (1.0 - u_sq / t1);
t3 = w1 * local_density;
t2 = t1 * c_sq;
t1 = u_sq / t1;
d_equ[1] = t3 * (1.0 + u[1] / c_sq + (u[1] * u[1]) / t2 - t1);
d_equ[2] = t3 * (1.0 + u[2] / c_sq + (u[2] * u[2]) / t2 - t1);
d_equ[3] = t3 * (1.0 + u[3] / c_sq + (u[3] * u[3]) / t2 - t1);
d_equ[4] = t3 * (1.0 + u[4] / c_sq + (u[4] * u[4]) / t2 - t1);
t3 = w2 * local_density;
d_equ[5] = t3 * (1.0 + u[5] / c_sq + (u[5] * u[5]) / t2 - t1);
d_equ[6] = t3 * (1.0 + u[6] / c_sq + (u[6] * u[6]) / t2 - t1);
d_equ[7] = t3 * (1.0 + u[7] / c_sq + (u[7] * u[7]) / t2 - t1);
d_equ[8] = t3 * (1.0 + u[8] / c_sq + (u[8] * u[8]) / t2 - t1);
for(kk = 0; kk < 9; kk++)
{
cells[pos].speeds[kk] = (tmp_cells[pos].speeds[kk] + params->omega *
(d_equ[kk] - tmp_cells[pos].speeds[kk]));
}
```

If someone wants to know the type of cells it is of type

```
typedef struct {
double speeds[NSPEEDS];
} t_speed;
```

## EDIT

After a few tests the problem is when I'm trying to set the values for each cells[pos].speeds[kk]. If I only change the value of one of the speeds then the results I get are better (more correct values). If I try to change more than one then the results are really bad.

So the thing is, why can't I change more than one values in the struct without having problems?

## EDIT

After trying to execute the whole code in a few loops, after a certain ammount of steps the above code leads to a segmentation fault. What causes the problem is of course the updating.

```
for(kk = 0; kk < 9; kk++)
{
cells[pos].speeds[kk] = (tmp_cells[pos].speeds[kk] + params->omega *
(d_equ[kk] - tmp_cells[pos].speeds[kk]));
}
```

If I comment this out then I get no segmentation faults.

## EDIT

When I target the cpu as the execution device for OpenCL the code executes fine without a problem. Why does this happen?