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Say I have an array of arbitrary size holding single characters. I want to compute all possible combinations of those characters up to an arbitrary length.

So lets say my array is [1, 2, 3]. The user-specified length is 2. Then the possible combinations are [11, 22, 33, 12, 13, 23, 21, 31, 32].

I'm having real trouble finding a suitable algorithm that allows arbitrary lengths and not just permutates the array. Oh and while speed is not absolutely critical, it should be reasonably fast too.

share|improve this question
Homework? And what is C++ specific about this? – anon Mar 4 '10 at 16:39
It's definitely not homework ;). I'll delete C++ from the tags, as this really is an algorithm question. – Milan Mar 4 '10 at 16:42
Are you sure 11, 22 and 33 are valid combinations? They would not be in the traditional definition of combination. – John Dibling Mar 4 '10 at 17:15
Of course they are, there is a total of 3^2 combinations, and that equals 9 ;) – Milan Mar 4 '10 at 17:30
"Combinations" is a mathematical term, as in N choose k. 3 choose 2 is clearly not 9. – Larry Mar 4 '10 at 17:49
up vote 7 down vote accepted

Just do an add with carry.

Say your array contained 4 symbols and you want ones of length 3.

Start with 000 (i.e. each symbol on your word = alphabet[0])

Then add up:

000 001 002 003 010 011 ...

The algorithm (given these indices) is just to increase the lowest number. If it reaches the number of symbols in your alphabet, increase the previous number (following the same rule) and set the current to 0.

C++ code:

int N_LETTERS = 4;
char alphabet[] = {'a', 'b', 'c', 'd'};

std::vector<std::string> get_all_words(int length)
  std::vector<int> index(length, 0);
  std::vector<std::string> words;

    std::string word(length);
    for (int i = 0; i < length; ++i)
      word[i] = alphabet[index[i]];

    for (int i = length-1; ; --i)
      if (i < 0) return words;
      if (index[i] == N_LETTERS)
        index[i] = 0;

Code is untested, but should do the trick.

share|improve this answer
Sounds interresting and seems to work in my mind. I'll test it out. Thanks for your answer! – Milan Mar 4 '10 at 16:55
Accepted your answer as I got it working and it's really a nice approach. Thank you again! – Milan Mar 4 '10 at 17:31
Intuitive and useful. Thanks! – Nate Glenn Jul 15 '11 at 14:50

One way to do it would be with a simple counter that you internally interpret as base N, where N is the number of items in the array. You then extract each digit from the base N counter and use it as an index into your array. So if your array is [1,2] and the user specified length is 2, you have

Counter = 0, indexes are 0, 0
Counter = 1, indexes are 0, 1
Counter = 2, indexes are 1, 0
Counter = 3, indexes are 1, 1

The trick here will be your base-10 to base-N conversion code, which isn't terribly difficult.

share|improve this answer

If you know the length before hand, all you need is some for loops. Say, for length = 3:

for ( i = 0; i < N; i++ )
   for ( j = 0; j < N; j++ )
      for ( k = 0; k < N; k++ )
         you now have ( i, j, k ), or a_i, a_j, a_k

Now to generalize it, just do it recursively, each step of the recursion with one of the for loops:

recurse( int[] a, int[] result, int index)
    if ( index == N ) base case, process result
        for ( i = 0; i < N; i++ ) {
           result[index] = a[i]
           recurse( a, result, index + 1 )

Of course, if you simply want all combinations, you can just think of each step as an N-based number, from 1 to k^N - 1, where k is the length.

Basically you would get, in base N (for k = 4):

0000 // take the first element four times
0001 // take the first element three times, then the second element
000(N-1) // take the first element three times, then take the N-th element
1000 // take the second element, then the first element three times
(N-1)(N-1)(N-1)(N-1) // take the last element four times
share|improve this answer
I'm aware of the first one - it is not applicable in my case due to arbitrary lengths. Recursion is not an option either, simply because of performance reasons and possible SO. Thanks for your answer though... – Milan Mar 4 '10 at 16:52
If you need to list everything and you're worried about stack overflow, you should also probably worry about finishing the algorithm before the universe ends. ;) Unless you have a trivial N = 1 case, even a modest 2^100 will probably take more than you imagine. If you have a specific case in mind, feel free to let me know! – Larry Mar 4 '10 at 16:57
Agree with Larry here. Stack overflow is the least of your issues. There are n^k words here. If k becomes any reasonable size, generating all words will take an unfathomable amount of time. – Peter Alexander Mar 4 '10 at 17:37

Knuth covers combinations and permutations in some depth in The Art of Computer Programming, vol 1. Here is an implementation of one of his algorithms I wrote some years ago (don't hate on the style, its ancient code):

#include <algorithm>
#include <vector>
#include <functional>
#include <iostream>
using namespace std;

template<class BidirectionalIterator, class Function, class Size>
Function _permute(BidirectionalIterator first, BidirectionalIterator last, Size k, Function f, Size n, Size level)
    // This algorithm is adapted from Donald Knuth, 
    //      "The Art of Computer Programming, vol. 1, p. 45, Method 1"
    // Thanks, Donald.
    for( Size x = 0; x < (n-level); ++x )   // rotate every possible value in to this level's slot
        if( (level+1) < k ) 
            // if not at max level, recurse down to twirl higher levels first
            f = _permute(first,last,k,f,n,level+1);
            // we are at highest level, this is a unique permutation
            BidirectionalIterator permEnd = first;
            advance(permEnd, k);
        // rotate next element in to this level's position & continue
        BidirectionalIterator rotbegin(first);
        BidirectionalIterator rotmid(rotbegin);
    return f;

template<class BidirectionalIterator, class Function, class Size>
Function for_each_permutation(BidirectionalIterator first, BidirectionalIterator last, Size k, Function fn)
    return _permute<BidirectionalIterator,Function,Size>(first, last, k, fn, distance(first,last), 0);

template<class Elem>
struct DumpPermutation : public std::binary_function<bool, Elem* , Elem*>
    bool operator()(Elem* begin, Elem* end) const
        cout << "[";
        copy(begin, end, ostream_iterator<Elem>(cout, " "));
        cout << "]" << endl;
        return true;

int main()

    int ary[] = {1, 2, 3};
    const size_t arySize = sizeof(ary)/sizeof(ary[0]);

    for_each_permutation(&ary[0], &ary[arySize], 2, DumpPermutation<int>());

    return 0;

Output of this program is:

[1 2 ]
[1 3 ]
[2 3 ]
[2 1 ]
[3 1 ]
[3 2 ]

If you want your combinations to include repeated elements like [11] [22] and [33], you can generate your list of combinations using the algorithm above, and then append to the generated list new elements, by doing something like this:

for( size_t i = 0; i < arySize; ++i )
    cout << "[";
    for( int j = 0; j < k; ++j )
        cout << ary[i] << " ";
    cout << "]" << endl;

...and the program output now becomes:

[1 2 ]
[1 3 ]
[2 3 ]
[2 1 ]
[3 1 ]
[3 2 ]
[1 1 ]
[2 2 ]
[3 3 ]
share|improve this answer
This won't work for anything other than 2-length words. The missing elements from the permutations are not just the ones only containing one symbol, but any that contain multiple of the same symbol. e.g. 121 isn't a permutation of {1,2,3}, and it isn't uniform either, so your algorithm won't generate it. – Peter Alexander Mar 4 '10 at 17:34
Why the downvote on this? – John Dibling Mar 4 '10 at 17:35
The question asker seems to like to downvote things. I don't know, I would like to ask that about my solution too. I up voted yours. – Larry Mar 4 '10 at 17:36
@Larry: Well, I think I see why it was downvoted. Poita_ was wrong in saying that my code doesn't handle arbitrary length strings, but correct in saying that repeated elements aren't dealt with properly. Still, the asker was looking for an algorithm, and I pointed them to TAoCP, which has many. Which in my opinion makes my response perfectly valid. – John Dibling Mar 4 '10 at 17:43
>The question asker seems to like to downvote things.< Not really. It wasn't me here, though I downvoted your answer Larry. After I realised that you were right, I already weren't allowed to remove my vote anymore. – Milan Mar 4 '10 at 18:27

Using Peter's algorithm works great; however, if your letter set is too large or your string size too long, attempting to put all of the permutations in an array and returning the array won't work. The size of the array will be the size of the alphabet raised to the length of the string.

I created this in perl to take care of the problem:

package Combiner;
#package used to grab all possible combinations of a set of letters. Gets one every call, allowing reduced memory usage and faster processing.
use strict;
use warnings;

#initiate to use nextWord
#arguments are an array reference for the list of letters and the number of characters to be in the generated strings.
sub new {
    my ($class, $phoneList,$length) = @_;
    my $self = bless {
        phoneList => $phoneList,
        length => $length,
        N_LETTERS => scalar @$phoneList,
    }, $class;

sub init {
    my ($self) = shift;
    $self->{lindex} = [(0) x $self->{length}];
    $self->{end} = 0;

#returns all possible combinations of N phonemes, one at a time. 
sub nextWord {
    my $self = shift;
    return 0 if $self->{end} == 1;
    my $word = [('-') x $self->{length}];

    $$word[$_] = ${$self->{phoneList}}[${$self->{lindex}}[$_]]

    #treat the string like addition; loop through 000, 001, 002, 010, 020, etc.
    for(my $i = $self->{length}-1;;$i--){
         if($i < 0){
            $self->{end} = 1;
            return $word;
         if (${$self->{lindex}}[$i] == $self->{N_LETTERS}){
            ${$self->{lindex}}[$i] = 0;
            return $word;

Call it like this: my $c = Combiner->new(['a','b','c','d'],20);. Then call nextWord to grab the next word; if nextWord returns 0, it means it's done.

share|improve this answer

Here's my implementation in Haskell:

g :: [a] -> [[a]] -> [[a]]
g alphabet = concat . map (\xs -> [ xs ++ [s] | s <- alphabet])

allwords :: [a] -> [[a]]
allwords alphabet = concat $ iterate (g alphabet) [[]]

Load this script into GHCi. Suppose that we want to find all strings of length less than or equal to 2 over the alphabet {'a','b','c'}. The following GHCi session does that:

*Main> take 13 $ allwords ['a','b','c']

Or, if you want just the strings of length equal to 2:

*Main> filter (\xs -> length xs == 2) $ take 13 $ allwords ['a','b','c']

Be careful with allwords ['a','b','c'] for it is an infinite list!

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This is written by me. may be helpful for u...

#include <unistd.h>
void main()
FILE *file;
int i=0,f,l1,l2,l3=0;
char set[]="abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ01234567890!@#$%&*.!@#$%^&*()";
int size=sizeof(set)-1;
char per[]="000";
//check urs all entered details here//
printf("Setlength=%d Comination are genrating\n",size);

// writing permutation here for length of 3//
//first for loop which control left most char printed in file//
// second for loop which control all intermediate char printed in file//
//third for loop which control right most char printed in file//
//apend file (add text to a file or create a file if it does not exist.//
file = fopen("file.txt","a+");
//writes array per to file named file.txt// 
///Writing to file is completed//
printf("Genrating Combination  %d\r",i);
printf("\n%d combination has been genrate out of entered data of length %d \n",i,size);
puts("No combination is left :) ");
puts("Press any butoon to exit");
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