I'm struggling to find efficient algorithm for calculating the rank of a permutation, and vice versa (permutation for a given rank). Can someone give some pointers?
Do you have repeating elements in the array? The following works if there are only using elements. Use the following recursion calculates the order of X[m:n] as a (nm+1) length permutation: Rank(X,m:n) = ( rank_of_element(X[m],X[m:n]) 1 ) * factorial(nm) + Rank(X,(m+1):n) Assume rank starts with 0. Basically, if you have a string EDCBA, then Rank(EDCBA) = Rank of first element starting with E (i.e. EABCD) + Rank of DCBA as a four letter string. This can be extended to non unique cases, but the first term needs to be updated: Rank(X,m:n) = Rank(X,(m+1):n) + \sum_(for y in X[m:n] such that y < X[m]) number of combinations of {X[m:n]}{y} . 


EDIT I just saw your comment. Nice graphic! Right what you want is a tree traversal. Notice how each position in your permutation has a distinct level in the tree? Every path from the root to a leaf node in that tree is a possible permutation. So this means that your 'rank' has some flexibility. You get to define it. Just make it whatever type of traversal you want over the tree (inorder, preorder, postorder, DFS,BFS) to give you a numbering of leaf nodes incremented as you go straight through each leaf node. So just choose the traversal and ranking of your permutations to be whatever you find most natural or convenient for your application. If you can't choose, ask /dev/random which traversal you should use. END EDIT Well first it has to be thought of like a base conversion. Every permutation is at a point (it's rank). Think of binary. What's an efficient algorithm for calculating a 2 alphabet permutation over n characters? Just assign the rank and you have the permutation. The same thing works for alphabets of other size. Obviously things are more complicated if your positions have different size alphabets, but you can still do the combinatorics :
Then to get permutation from rank just use a radix formula : I seem to remember:
If you think about it from this combinatorical and radix perspective, you can't go wrong, even in more complex cases. Just take whatever rank you want and convert it into the base that's appropriate for your alphabet. You may be interested in Mixed Radix Conversion on Wikipedia, here 


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issues on the right, you'll find many duplicates. – user unknown Feb 19 '12 at 11:46