# h(k) = k mod m, where k is a character string interpreted in radix 2^p and m = 2^p – 1. Show that h(x) = h(y)

The full question is:

Consider the hash function:

`h(k) = k mod m`, where k is a character string interpreted in radix 2p and m = 2p – 1. Show that by permuting characters in string `y` we can derive string `x ⇒ x` and `y` hash to the same value.

I have decided that there are two ways to solve this problem. I can either show that

`h(x) - h(y) = 0` or

h(x) = (x * (2p - 1)) % (2p - 1) which would always equal 0 no matter what x we use

I've looked up several solutions online but I'm very confused with this problem. I think my biggest problem is I'm not sure how I'm supposed to use the radix information to solve this problem.

Can I get a hint as to how I should begin this problem?

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Do you know the old trick to quickly determine whether a number is divisible by 9? It's the same principle. –  Daniel Fischer Dec 3 '12 at 10:44
So that's the idea with the line "interpreted in radix 2^p"? I need to add up the values of each char and show that the total is the same no matter the order. I'll work on it! –  user1754045 Dec 3 '12 at 10:52
You are essentially asked to prove a generalised version of the divisible by 9 trick. –  Daniel Fischer Dec 3 '12 at 10:58

if `m = 2^p - 1` and k is a character string interpreted in `radix 2^p`, Then two strings that are identical except for a transposed character hash to the same value For example let `m = 2^3 - 1 = 7` and using ASCII values for characters:

String ``abcd'' is represented as

k = 97 . 8^3 + 98 . 8^2 + 99 . 8 + 100 = 56828
which hashes 56828 mod 7 = 2.