From Permutation to Number:

Let K be the number of character classes (example: AAABBC has three character classes)

Let N[K] be the number of elements in each character class. (example: for AAABBC, we have N[K]=[3,2,1], and let N= sum(N[K])

Every legal permutation of the sequence then uniquely corresponds to a path in an incomplete K-way tree.

The unique number of the permutation then corresponds to the index of the tree-node in a post-order traversal of the K-ary tree *terminal nodes*.

Luckily, we don't actually have to perform the tree traversal -- we just need to know how many terminal nodes in the tree are *lexicographically less* than our node. This is very easy to compute, as at any node in the tree, the number terminal nodes *below* the current node is equal to the number of permutations using the unused elements in the sequence, which has a closed form solution that is a simple multiplication of factorials.

So given our 6 original letters, and the first element of our permutation is a 'B', we determine that there will be 5!/3!1!1! = 20 elements that started with 'A', so our permutation number has to be greater than 20. Had our first letter been a 'C', we could have calculated it as 5!/2!2!1! (not A) + 5!/3!1!1! (not B) = 30+ 20, or alternatively as
60 (total) - 5!/3!2!0! (C) = 50

Using this, we can take a permutation (e.g. 'BAABCA') and perform the following computations:
Permuation #= (5!/2!2!1!) ('B') + 0('A') + 0('A')+ 3!/1!1!1! ('B') + 2!/1!

= 30 + 3 +2 = 35

Checking that this works: CBBAAA corresponds to

(5!/2!2!1! (not A) + 5!/3!1!1! (not B)) 'C'+ 4!/2!2!0! (not A) 'B' + 3!/2!1!0! (not A) 'B' = (30 + 20) +6 + 3 = 59

Likewise, AAABBC =
0 ('A') + 0 'A' + '0' A' + 0 'B' + 0 'B' + 0 'C = 0

Sample implementation:

```
import math
import copy
from operator import mul
def computePermutationNumber(inPerm, inCharClasses):
permutation=copy.copy(inPerm)
charClasses=copy.copy(inCharClasses)
n=len(permutation)
permNumber=0
for i,x in enumerate(permutation):
for j in xrange(x):
if( charClasses[j]>0):
charClasses[j]-=1
permNumber+=multiFactorial(n-i-1, charClasses)
charClasses[j]+=1
if charClasses[x]>0:
charClasses[x]-=1
return permNumber
def multiFactorial(n, charClasses):
val= math.factorial(n)/ reduce(mul, (map(lambda x: math.factorial(x), charClasses)))
return val
```

From Number to Permutation:
This process can be done in reverse, though I'm not sure how efficiently:
Given a permutation number, and the alphabet that it was generated from, recursively subtract the largest number of nodes less than or equal to the remaining permutation number.

E.g. Given a permutation number of 59, we first can subtract 30 + 20 = 50 ('C') leaving 9. Then we can subtract 'B' (6) and a second 'B'(3), re-generating our original permutation.

`{1,2,3}=={1,2,3,2,1}`

. Can you clarify your question ? – High Performance Mark Jan 8 '13 at 9:43