#pragma omp parallel for
for (int i = 2; i < N; i++)
for (int j = 2; j < N; j++)
arr[i][j] = arr[i-2][j] +arr[i][j-2];
is always going to be a source of grief and unpredictable output. The OpenMP run time is going to hand each thread a range of values for
i and leave them to it. There will be no determinism in the relative order in which threads update
arr. For example, while thread 1 is updating elements with
i = 2,3,4,5,...,100 (or whatever) and thread 2 is updating elements with
i = 102,103,104,...,200 the program does not determine whether thread 1 updates
arr[i,:] = 100 before or after thread 2 wants to use the updated values in
arr. You have written a code with a classic data race.
You have a number of options to fix this:
You could tie yourself in knots trying to ensure that the threads update
arr in the right (ie sequential) order. The end result would be an OpenMP program that runs more slowly than the sequential program. DO NOT TAKE THIS OPTION.
You could make 2 copies of
arr and always update from one to the other, then from the other to the one. Something like (very pseudo-code)
old = 0
new = 1
arr[i][j][new] = arr[i-2][j][old] +arr[i][j-2][old];
old = 1
new = 0
Of course, this second approach trades space for time but that's often a reasonable trade-off.
You may find that adding an extra plane to
arr doesn't immediately speed things up because it wrecks the spatial locality of values pulled into cache. Experiment a bit with this, possibly make
[old] the first index element rather than the last.
Since updating each element in the array depends on the values found in elements 2 rows/columns away you're effectively splitting the array up like a chess-board, into white and black elements. You could use 2 threads, one on each 'colour', without the threads racing for access to the same data. Again, though, the disruption of spatial locality in the cache might have a bad impact on speed.
If any other options occur to me I'll edit them in.