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I'm dealing with covering arrays and need some guidance about generating sets (given certain parameters) for computing whether an array is a covering array or not.

I'm given two inputs to parse - t and v as integers. v contains the number of unique symbols (integers) in the array. This can be assumed to be a set of any integers. The integer t represents the length of symbols I want to grab from this set.

So for example, assume v = 3 for {0,1,2} as symbols, and t = 2. Then I will be generating the combinations { (0,0), (0,1), (0,2), (1,0), (1,1), (1,2), ..., (2,2) }. In general, I will be generating v^t combinations. I am wondering if there is a better algorithm than the one I have been using which may be, perhaps, less computationally expensive.

Basically what I am doing is counting in a different base. So, for instance, in the above example I initially start with an array that has t spaces allocated to 0. On each pass, I increment the least significant bit and convert this to a set or some other data structure to hold my combinations. Once the least significant bit overflows, I set it to 0 and increment the next significant bit. It's all counting in different bases. So I'd end up with the following output for t=2 and v=3:


My biggest question is this - is this a permutation or combination problem? I'm a little fuzzy on the details between the two. I believe it is permutation just because repetition occurs, and because order doesn't matter.

Likewise, is this algorithm decent enough to (potentially) handle a large v? I am given the parameter that t will be 2 or 3, but v is unknown. Is there a well-known algorithm for computing length-t sets on v symbols? For reference, I am using C++ to do this.

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The amortized cost of counting goes down as v increases, because you spend a smaller percentage of the time propagating the carry. – Oliver Charlesworth Feb 12 '13 at 22:36
@bgoers: In your example {01} and {10} are different, so its not a combinations only problem - possible permutations of combinations. – user760577 Feb 12 '13 at 23:01
@OliCharlesworth Thanks for the input. So assuming (which I safely can in this case due to constraints) that v <= 500, do you believe this will be fine? At that point I'm assuming it's more a question of space complexity, but this is running on a rather large cluster so I am not too terribly worried.. – bgoers Feb 12 '13 at 23:05
up vote 2 down vote accepted

You're dealing with variations with repetitions. There's plenty of examples, both on SO and all over the Internet. As for your algorithm, it's complexity will be at least the size of the output - which you've already pointed it out - it'll be Ω(v^t). If bit-wise operations work for you (i.e. fit with the rest of the implementation) then yes, you can do it this way.

share|improve this answer
Awesome! Thanks for the info. I have been searching high and low for a specific name for this type of problem, just hadn't nailed it down specifically. – bgoers Feb 12 '13 at 23:10

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