I'm writing some code and ended up with this problem. I have N products and I have to form all possible combinations of these products, form a product catalog and find some properties, like price. In order to do this I have to form the catalog of products from the given products (exhaustively, but no duplicates allowed). Is there a standardized algorithm for doing this? Note that the catalogs can contain any positive number of products.
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The first few sections of The Art of Computer Programming, vol. 3, Sorting and Searching discusses Inversion and Permutation (of a set and multisets) in great detail. In this case it is important to dabble in theory a bit, see what's out there. The code will follow, but if this is "leisure time coding", why not do it including "leisure time theory" as well? Betcha it's going to be cool, you'll know the whats but you'll also know the whys! 


Combinations can be represented by a bitvector. If a bit is set, the element is present in the combination. So you simply have to enumarte all numbers from 1 to 2^N1 (from 0000001, last element present till 1111111, all elements present), and will represent a possible combination. 


A naive implementation to print all combination of characters from a give string:
Quite simple but may have performance problem. Take it if it could help. If you're looking for permutation(I can't tell from your description), I implemented the algorithm in The Art of Computer Programming:
It's quite efficient and C++ stl algorithm uses the same algorithm. 


You can do this in python, using itertools.combinations in following way:
what gives as result:
Solution inspired by this answer of @danh. 


for i = 1 to 2^N
and use bit hax... I think... – quasiverse Aug 29 '11 at 12:05any positive number
is much too vague. For very small numbers, the problem is solvable in memory, but soon it isn't.exhaustively
is a word, you surely don't like to hear in that context. See yi_H's answer, and think about 2^65 combinations for 65 elements. – user unknown Aug 29 '11 at 13:23