I'm writing a program where I'm having to test if one set of unique integers `A`

belongs to another set of unique numbers `B`

. However, this operation might be done several hundred times per second, so I'm looking for an efficient algorithm to do it.

For example, if `A = [1 2 3]`

and `B = [1 2 3 4]`

, it is true, but if `B = [1 2 4 5 6]`

, it's false.

I'm not sure how efficient it is to just sort and compare, so I'm wondering if there are any more efficient algorithms.

One idea I came up with, was to give each number `n`

their corresponding `n`

'th prime: that is 1 = 2, 2 = 3, 3 = 5, 4 = 7 etc. Then I could calculate the product of `A`

, and if that product is a factor of the similar product of `B`

, we could say that `A`

is a subset of similar `B`

with certainty. For example, if `A = [1 2 3]`

, `B = [1 2 3 4]`

the primes are [2 3 5] and [2 3 5 7] and the products 2*3*5=30 and 2*3*5*7=210. Since 210%30=0, `A`

is a subset of `B`

. I'm expecting the largest integer to be couple of million at most, so I think it's doable.

Are there any more efficient algorithms?

`long`

s or arbitrarily big (limited to your pc's memory) if you use big ints)? If they are not very constrained, you can simply forget about your prime numbers, the algorithm will be painfully slow, and unless you use some "bigint" you will get integer overflows and it won't work. – Bruno Reis Aug 1 '11 at 4:24