This code works by using the connection between binary numbers with exactly n bits and subsets of a set of n elements. If you assign each element of the set to a single bit and treat "1" to mean "include the element in the subset" and "0" to mean "exclude the element from the subset," then you can easily convert between the two. For example, if the set contains a, b, and c, then 100 might correspond to the subset a, 011 to the subset bc, etc. Try reading through the code again with this insight.

In terms of efficiency, the above code is very fast both practically and theoretically. Any code that lists subsets has to spend some large amount of time just listing off those subsets. The time required is proportional to the total number of elements that have to be listed. This code spends O(1) work per item listed and therefore is asymptotically optimal (assuming, of course, that there aren't so many elements that you overflow the ints being used).

The total complexity of this code can be determined by counting how many total elements get printed. We can work out some math to solve this. Note that there are n choose 0 subsets of size 0, n choose 1 subsets of size 1, n choose 2 subsets of size 2, etc. Therefore, the total number of elements printed is given by

C = 0 × (n choose 0) + 1 × (n choose 1) + 2 × (n choose 2) + … + n × (n choose n)

Note that (n choose k) = (n choose n - k). Therefore:

C = 0 × (n choose n) + 1 × (n choose n - 1) + 2 × (n choose n - 2) + … + n × (n choose 0)

If we add these two together, we get

2C = n × (n choose 0) + n × (n choose 1) + … + n × (n choose n)

= n × (n choose 0 + n choose 1 + … + n choose n)

The binomial theorem says that the parenthesized expression is 2^{n}, so

2C = n2^{n}

So

C = n2^{n-1}

So exactly n2^{n-1} elements are printed, so the time complexity of this approach is Θ(n 2^{n}).

Hope this helps!