# get all subsets of a specific set iteratively

I know the iterative solution:

given a set of `n` elements

save an `int v = 2^n` and generate all binaries number up to this `v`.

But what if n > 32?

I know it's already 2^32 subsets, but yet - what's the way to bypass the 32 elements limitation?

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What about making an array of ints, and manually propagating the carry bit to one int to the next one? Like `[0000][1111] -> [0001][0000]` BTW, wouldn't it be terribly/impossibly slow? – biziclop Feb 9 '13 at 12:16
Use `long` to go up to n=64. If n > 64, then it will take your program several centuries to enumerate all the subsets, so you should look for a solution to the original problem that doesn't involve enumerating subsets. – Raymond Chen Feb 9 '13 at 12:49
why in the world would you want to do this? that's like one very long for loop... is this an xy problem? – thang Feb 9 '13 at 13:15
I'd do exactly whit biziclop suggests. You're probably aware of the exponential runtime of that approach so you're probably not interested in actually running the enumeration, is that right? – G. Bach Feb 9 '13 at 14:13

## 3 Answers

1. If you're happy with a 64 item limit, you can simply use `long`.

2. Array / `ArrayList` of `int`s / `long`s. Have a `next` function something like:

``````bool next(uint[] arr)
for (int i = 0; i < arr.length; i++)
if (arr[i] == 2^n-1) // 11111 -> 00000
arr[i] = 0
else
arr[i]++
return true
return false // reached the end -> there is no next
``````
3. BitArray. Probably not a very efficient option compared to the above.

You can have a `next` function which sets the least significant bit 0 to 1 and all remaining bits to 0. e.g.:

``````10010 -> 10011
10011 -> 10100
``````

Note - this will probably take forever, simply because there's so many subsets, but that's not the question.

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You can use @biziclop approach, by propagating the carry bit in the following way: store your number as vector of 32-bit "digits" of length K. So, you can generate 2^(K*32) subsets, and every increment operation will take at most O(K) operations. The other thing that I can think of is recursive backtrack, that will generate all subsets in one array.

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You could write an analog of this concise Haskell implementation:

``````powerSet = filterM (const [True, False])
``````

Except there is no built-in `filterM` in C#. That's no problem, you can implement it yourself. Here is my attempt at it:

``````public static IEnumerable<IEnumerable<T>> PowerSet<T>(IEnumerable<T> els)
{
return FilterM(_ => new[] {true, false}, els);
}

public static IEnumerable<IEnumerable<T>> FilterM<T>(
Func<T, IEnumerable<bool>> p,
IEnumerable<T> els)
{
var en = els.GetEnumerator();
if (!en.MoveNext())
{
yield return Enumerable.Empty<T>();
yield break;
}

T el = en.Current;
IEnumerable<T> tail = els.Skip(1);
foreach (var x in
from flg in p(el)
from ys in FilterM(p, tail)
select flg ? new[] { el }.Concat(ys) : ys)
{
yield return x;
}
}
``````

And then you can use it like this:

``````foreach (IEnumerable<int> subset in PowerSet(new [] { 1, 2, 3, 4 }))
{
Console.WriteLine("'{0}'", string.Join(",", subset));
}
``````

As you can see, neither `int` nor `long` are explicitly used anywhere in the implementation, so the real limit here is the maximum recursion depth reachable with the current stack size limit.

UPD: Rosetta Code gives a non-recursive implementation:

``````public static IEnumerable<IEnumerable<T>> GetPowerSet<T>(IEnumerable<T> input)
{
var seed = new List<IEnumerable<T>>() { Enumerable.Empty<T>() }
as IEnumerable<IEnumerable<T>>;

return input.Aggregate(seed, (a, b) =>
a.Concat(a.Select(x => x.Concat(new List<T> { b }))));
}
``````
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