# Find the index of a given permutation in the list of permutations in lexicographic order [duplicate]

This is an interview question. Let there is a list of permutations in lexicographic order. For example, `123`, `132`, `213`, `231`, `312`, `321`. Given a permutation find its index in such a list. For example, the index of permutation `213` is 2 (if we start from 0).

Trivially, we can use a `next_permutation` algorithm to generate a next permutation in lexicographic order, but it leads to O(N!) solution, which is obviously non-feasible. Is there any better solution?

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## marked as duplicate by Oded♦, Jeff Atwood♦May 9 '11 at 11:37

This solution came into my mind (but I didn't test it yet).

The first digit is from range 1 to N, thus you can derive from the first digit whether your permutation is in which block of size (N-1)!

``````2*(2!) + X where X = 0..2!-1
``````

Then you can recursively apply this to the next digits (which is one of (N-1)! permutations).

So with an arbitrary N you can do the following algorithm:

``````X = 0
while string <> ""
X += ((first digit) - 1) * (N-1)!
decrease all digits in string by 1 which are > first digit
remove first digit from string
N -= 1
return X
``````

``````X = 2
s = "213"
X += (2-1) * 2! => 2
s = "12"
X += (1-1) * 1! => 2
s = "1"
X += (1-1) * 0! => 2
``````

Thus this algorithm is O(N^2).

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Multiply the index of the first digit among the digits in the permutation by `(n-1)!` and add the index of the remaining permutation.

For example, `2` has index `1`, and the index of `13` is `0`, so the result is `1 * (3-1)! + 0 = 1 * 2 = 2`.

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• First element in the permutation gives you a subrange of `N!`
• Remove first element
• Renumber the remaining elements to remove gaps
• Recurse
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In C using recursion it will be something like this

```int index(char *abc, int size)
{
if(abc ==0 || *abc==0 || size == 0)
{
return 0;;
}
return ((abc[0] - '0') * pow(2,size-1)) + index(abc + 1, size -1);
}
```
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