Factorize each element of either array, sort, cancel. Factorization is constant time for ints of bounded size, sorting is n log n, and cancellation will be linear. The constant factors may be large, though.
If you're trying for lower actual execution time instead of lower asymptotic complexity, it probably wouldn't hurt to preprocess the arrays by manually cancelling small factors, such as powers of 2, 3, 5, and 7. With high probability (i.e. except for pathological inputs), this will speed up most algorithms immensely, at the cost of a few linear-time passes.
One more sophisticated method, integrating the above approaches, would be to start by building a list of primes up to
sqrt(10^7) ~= 3162. There should be about
3162/ln(3162) ~= 392 such primes, by the prime number theorem. (In fact, to save running time, you could/should precompute this table.)
Then, for each such integer in
N, and for each prime, reduce the integer by that prime until it no longer divides evenly, and each time increment a count for that prime. Do the same for
D, decrementing instead. Once you've gone through the table of primes, the current int will be non-1 if and only if it is a prime larger than 3162. This should be about 7% of the total integers in each array. You can keep these in a heap or somesuch. Set them to ones in the array as well, as you go along.
Finally, you iterate over the positive factors and put their product into N. You will probably need to split this across multiple array slots, which is fine. Put the negative factors into D, and you're done!
The runtime on this will take me a minute to work out. Hopefully, it's reasonable.