While researching for a project euler exercise (#78), I've learned that in order to partition a number you can create a power series. From that series you can expand and use the terms coefficient to get the number of ways to partition a particular number.
From there, I've created this small function:
## I've included two arguments, 'lim' for the number you wish to partition and 'ways' a list of numbers you can use to partition that number 'lim'. ## def stack(lim,ways): ## create a list of length of 'lim' filled with 0's. ## posi =  * (lim + 1) ## allow the posi to be 1 ## posi = 1 ## double loop -- with the amount of 'ways'. ## for i in ways: for k in range(i, lim + 1): posi[k] += posi[k - i] ## return the 'lim' numbered from the list which will be the 'lim' coefficient. ## return posi[lim] >>> stack(100,[1,5,10,25,50,100]) >>> 293 >>> stack(100,range(1,100)) >>> 190569291 >>> stack(10000,range(1,10000)) >>> 36167251325636293988820471890953695495016030339315650422081868605887952568754066420592310556052906916435143L
This worked fine on relatively small partitions but, with not with this exercise. Are there ways to speed this up possibly with recursion or a faster algorithm? I've read some places that using pentagonal numbers is a way to help with partitions too.
Now I don't need to return the actually number on this problem but, check if it is evenly divisible by 1000000.
Update: I ended up using the pentagonal number theorem. I am going to be attempting to use the Hardy-Ramanujan asymptotic formula that Craig Citro had posted.