# Finding all the unique permutations of a string without generating duplicates

Finding all the permutations of a string is by a well known Steinhaus–Johnson–Trotter algorithm. But if the string contains the repeated characters such as
AABB,
then the possible unique combinations will be 4!/(2! * 2!) = 6

One way of achieving this is that we can store it in an array or so and then remove the duplicates.

Is there any simpler way to modify the Johnson algorithm, so that we never generate the duplicated permutations. (In the most efficient way)

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What is the definition of permutation? Is BA a valid permutation of AABB? –  ElKamina Feb 9 '12 at 20:06
no BA is not a valid permutation of AABB. –  titan Feb 9 '12 at 20:07
Permutation is the one sequence of shuffling the characters in the string. For a string of length n and unique characters we have a total of n! possible unique permutations –  titan Feb 9 '12 at 20:08
You can modify Jhonson algorithm, by putting each appear of every letter in one step. –  asaelr Feb 9 '12 at 20:24
If you can't find a way to avoid generating duplicates, you might benefit from removing duplicates as you're generating them by storing the permutations in a self-balancing BST or similar sorted structure. –  Brian McFarland Feb 9 '12 at 20:39

I think this problem is essentially the problem of generating multiset permutations. this paper seems to be relevant: J. F. Korsh P. S. LaFollette. Loopless array generation of multiset permutations. The Computer Journal, 47(5):612–621, 2004.

From the abstract: This paper presents a loopless algorithm to generate all permutations of a multiset. Each is obtained from its predecessor by making one transposition. It differs from previous such algorithms by using an array for the permutations but requiring storage only linear in its length.

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Well done, this looks like exactly it. –  Matt Phillips Feb 9 '12 at 21:20
And what about to try and to write it yourself? –  Gangnus Feb 9 '12 at 21:57

Use the following recursive algorithm:

``````PermutList Permute(SymArray fullSymArray){
PermutList resultList=empty;
for( each symbol A in fullSymArray, but repeated ones take only once) {
PermutList lesserPermutList=  Permute(fullSymArray without A)
for ( each SymArray item in lesserPermutList){
}
}
return resultList;
}
``````

As you see, it is very easy

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In my solution, I generate recursively the options, try every time to add every letter that I didn't use as many times I need yet.

``````#include <string.h>

void fill(char ***adr,int *pos,char *pref) {
int i,z=1;
//loop on the chars, and check if should use them
for (i=0;i<256;i++)
if (pos[i]) {
int l=strlen(pref);
pref[l]=i;
pos[i]--;
//call the recursion
//delete the char
pref[l]=0;
pos[i]++;
z=0;
}
}

void calc(char **arr,const char *str) {
int p[256]={0};
int l=strlen(str);
char temp[l+1];
for (;l>=0;l--) temp[l]=0;
while (*str) p[*str++]++;
fill(&arr,p,temp);
}
``````

use example:

``````#include <stdio.h>
#include <string.h>

int main() {
char s[]="AABAF";
char *arr[20];
int i;
for (i=0;i<20;i++) arr[i]=malloc(sizeof(s));
calc(arr,s);
for (i=0;i<20;i++) printf("%d: %s\n",i,arr[i]);
return 0;
}
``````
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Added some comments. any more suggestions? –  asaelr Feb 9 '12 at 22:48
The most important improvement, even more so than comments, would be descriptive function/variable names. Right now you have two functions named `func` and `calc`, and variables named `arr`, `pref`, `pos`, `adr`, `p`, `l`, `i`, `z`, `p`, `s`, and `str`; none of their purposes are obvious by their names. Using more descriptive variable names will do wonders for the readability of your code. –  BlueRaja - Danny Pflughoeft Feb 9 '12 at 23:09
Other smaller improvements: use descriptive types (`z` should be `bool`, `#include <stdbool.h>`); don't use magic numbers (the size of `arr`, the size of `p`); don't use `strcpy()` for anything, ever; don't forget to call `free()` on your `malloc()`'s :) –  BlueRaja - Danny Pflughoeft Feb 9 '12 at 23:15

First convert the string to a set of unique characters and occurrence numbers e.g. BANANA -> (3, A),(1,B),(2,N). (This could be done by sorting the string and grouping letters). Then, for each letter in the set, prepend that letter to all permutations of the set with one less of that letter (note the recursion). Continuing the "BANANA" example, we have: permutations((3,A),(1,B),(2,N)) = A:(permutations((2,A),(1,B),(2,N)) ++ B:(permutations((3,A),(2,N)) ++ N:(permutations((3,A),(1,B),(1,N))

Here is a working implementation in Haskell:

``````circularPermutations::[a]->[[a]]
circularPermutations xs = helper [] xs []
where helper acc [] _ = acc
helper acc (x:xs) ys =
helper (((x:xs) ++ ys):acc) xs (ys ++ [x])

nrPermutations::[(Int, a)]->[[a]]
nrPermutations x | length x == 1 = [take (fst (head x)) (repeat (snd (head x)))]
nrPermutations xs = concat (map helper (circularPermutations xs))
where helper ((1,x):xs) = map ((:) x)(nrPermutations xs)
helper ((n,x):xs) = map ((:) x)(nrPermutations ((n - 1, x):xs))
``````
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