It's possible to simply submit a query to WolframAlpha, and get back an approximate answer within a fraction of a second (at least for 2,000!, or even 10,000,000,000!), which, if you only need an approximation for large factorials, will probably be more than enough.

Here's a wikipedia article on the challenges around calculating large factorials by yourself, some of which you've already discovered.

What you'll really want to do is try to reduce the total amount of work that needs to be done. The simplest way to do this is to store the results in a table, and do a lookup. The table to contain all these values can be quite large, but that's one method if storage isn't a limitation in your situation.

Simply trying to parallelize it won't save you on CPU (unless you're calculating an approximation, as opposed to the precise number), because you're doing to same amount of total work, but spreading it out. Also, parallelizing anything involves some overhead (inter-thread/inter-process communication, distributed memory if the problem space is large enough, all kinds of things). The places where parallelizing any algorithm is a big win, is when you can successfully split up the problem into smaller chunks, and spread those chunks out efficiently enough so that the time to...

- send the chunks out out
- have the chunks calculated
- send the results back
- combine the results

...is less costly (as measured in time, money, storage, electricity, or whatever your limited resource is) than doing it series, and/or that it provides some value (time, money, storage, etc. **saved**) so that it effectively makes up for the cost.

`O(n^1.585)`

. FFT is the one that gets near`O(n log n)`

. – Mysticial Jan 6 '12 at 18:55