Ranking and unranking of permutations with duplicates

From the abstract of a paper:

A ranking function for the permutations on n symbols assigns a unique integer in the range [0, n! - 1] to each of the n! permutations. The corresponding unranking function is the inverse: given an integer between 0 and n! - 1, the value of the function is the permutation having this rank.

I made a ranking and an unranking function in C++ using next_permutation. But this isn't practical for n>8. I'm looking for a faster method and factoradics seem to be quite popular. But I'm not sure if this also works with duplicates. So what would be a good way to rank/unrank permutations with duplicates?

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Depends, what kind of permutation are you using ? I mean, what's the original set and the ranking function ? –  Yochai Timmer Jul 30 '11 at 17:22
It's in lexicographical order. So if a permutation has rank r, the next permutation has rank r+1. The same permutation should have the same rank (in the case of duplicates). –  Jasper Aug 1 '11 at 5:51

One way is to rank and unrank the choice of indices by a particular group of equal numbers, e.g.,

``````def choose(n, k):
c = 1
for f in xrange(1, k + 1):
c = (c * (n - f + 1)) // f
return c

def rank_choice(S):
k = len(S)
r = 0
j = k - 1
for n in S:
for i in xrange(j, n):
r += choose(i, j)
j -= 1
return r

def unrank_choice(k, r):
S = []
for j in xrange(k - 1, -1, -1):
n = j
while r >= choose(n, j):
r -= choose(n, j)
n += 1
S.append(n)
return S

def rank_perm(P):
P = list(P)
r = 0
for n in xrange(max(P), -1, -1):
S = []
for i, p in enumerate(P):
if p == n:
S.append(i)
S.reverse()
for i in S:
del P[i]
r *= choose(len(P) + len(S), len(S))
r += rank_choice(S)
return r

def unrank_perm(M, r):
P = []
for n, m in enumerate(M):
S = unrank_choice(m, r % choose(len(P) + m, m))
r //= choose(len(P) + m, m)
S.reverse()
for i in S:
P.insert(i, n)
return tuple(P)

if __name__ == '__main__':
for i in xrange(60):
print rank_perm(unrank_perm([2, 3, 1], i))
``````
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Could you explain your code a little? Thx –  Jasper Aug 1 '11 at 5:48

For large n-s you need arbitrary precision library like GMP.

this is my previous post for an unranking function written in python, I think it's readable, almost like a pseudocode, there is also some explanation in the comments: Given a list of elements in lexicographical order (i.e. ['a', 'b', 'c', 'd']), find the nth permutation - Average time to solve?

based on this you should be able to figure out the ranking function, it's basically the same logic ;)

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