# Is there effective algorithm that will return all different combination?

EDITED: I meant COMBINATION and not PERMUTATIONS

Is there effective algorithm that will return all different permutations from the given array? ["A", "B", "C", "D", "E", "F", "G", "H", "I", "J", "K", ...]

I found some algorithms, but they return ALL permutation and not different ones. By different I mean that:

1. AB & BA are the same permutations

2. DEF & FED & EFD & DFE are the same permutations,

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What you want are `subsets`, not `permutations` – Dr. belisarius Jul 6 '11 at 17:16
So you mean combinations, not permutations? – Oliver Charlesworth Jul 6 '11 at 17:16
If order matters, it is a permutation. If not, it is a combination. Are you looking for a combination algorithm? – Kal Jul 6 '11 at 17:18
– sdcvvc Jul 7 '11 at 12:06
Can you please mark a correct answer? – Corey Ogburn Jul 29 '11 at 16:55

The best I can think is sort of a binary counter:

`````` A B C
-------
0 0 0 | Empty Set
0 0 1 | C
0 1 0 | B
0 1 1 | BC
1 0 0 | A
1 0 1 | AC
1 1 0 | AB
1 1 1 | ABC
``````
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+1 for the nice table demonstrating how the binary counter works. – Chris Jul 6 '11 at 17:25
The answer would then be 2^n, where n = number of letters. – Dan Spiteri Jul 7 '11 at 4:08
Ah yes, the big O. I should have stated that. – Corey Ogburn Jul 7 '11 at 14:20

Any given item is either in the combination or not. Think of a boolean flag for each item, saying whether it's in the combination. If you go through every possible list of values of the boolean flags, you've gone through every combination.

Lists of boolean values are also called binary integers.

If you have items A-K, you have 11 items. So, go through all the possible 11-bit numbers. In Java:

``````for (int flags = 0; flags < (1 << 11); ++flags) {
int x = indexOfSomeItemFromZeroToTen();
boolean isInCombination = ((i >> x) & 1) == 1;
}
``````

Start at 1 instead of 0 if you want to skip the empty combination.

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Should that have been ++flags rather than ++i? – Chris Jul 6 '11 at 17:24
Whoops! Thanks. – Tom Anderson Jul 6 '11 at 17:25
1. As pointed out by the comments, you are looking to enumerate all subsets, not permutations.

2. The easiest way to do this is to use a binary counter. For example, suppose you have n-elements, then something like this would work in C:

code:

``````for(int i=0; i<(1<<n); ++i)  {
//Bits of i represent subset, eg. element k is contained in subset if i&(1<<k) is set.
}
``````

I hope this helps answer your question

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Here is some Ruby code I've written and had for a while now that iterates through each combination in an array.

``````def _pbNextComb(comb,length) # :nodoc:
i=comb.length-1
begin
valid=true
for j in i...comb.length
if j==i
comb[j]+=1
else
comb[j]=comb[i]+(j-i)
end
if comb[j]>=length
valid=false
break
end
end
return true if valid
i-=1
end while i>=0
return false
end

#
# Iterates through the array and yields each
# combination of _num_ elements in the array
#
# Takes an array and the number of elemens
# in each combination
def pbEachCombination(array,num)
return if array.length<num || num<=0
if array.length==num
yield array
return
elsif num==1
for x in array
yield [x]
end
return
end
currentComb=[]
arr=[]
for i in 0...num
currentComb[i]=i
end
begin
for i in 0...num
arr[i]=array[currentComb[i]]
end
yield arr
end while _pbNextComb(currentComb,array.length)
end
``````
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These are not permutations. The permutations of `ABC` are `{ABC, ACB, BCA, BAC, CAB, CBA}`. You are interested in finding all distinct subsets (otherwise known as the power set) of `{A,B,C, ..., K, ...}`. This is easy to do: each element can be either included or excluded. Here's a recursive algorithm:

``````power_set(U) =
if U == {} then
{{}};
else
union( { first(U), power_set(tail(U)) },  // include
{ power_set(tail(U)) }             // exclude
);
``````
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