# Given a high number of elements |M| with a constant length of |m|, which algorithm can index |M| with a length <|m|?

This question is language independent, so I adress all of you intelligent programers to help me somehow.

Given is a set of elements "M" with |M| = 2^128 elements. Every element "m" has a bit-length of 128 bits.

I want to send a message with the length of 128 Bit. In this message, I want to incorporate one of the elements of M and some information "n". That means, "m" and "n" have to be in length < 128 bit (length of the message).

The other party has the complete set "M" with all elements, but I need to tell him/her which element she/he has to use. This instruction has to fit in one meassage and can't be splitt up several messages.

So, I want to index my elements with an algotithm f(), so that f(m)=index_of_m with index_of_m<128 bit.

In other words, the algorithm has to map 2^128 elements of a length of 128 bit on an index that is represented with less bits than the length of the elements (128 bit).

Formal again:

The set:

``````M=(m1,m2,...mn) with n = 2^128
``````

Length of every `m1...mn: 128 bits.`

A message `"n" < 128 bit`. Message length is variable and could be 1 bit.

Indexing/mapping function: f()

``````f(m1)=i1  Index 1 of element m1 with the length of i1 < 128 bit., so i1+n=128bit
Wanted: Function f().
``````

Ideas:

-Hashes won't work in a simplistic way of hashing the elements, as a hash with a 64bit output can' encode the 2^128 elements. A hash with a 128 bit output will use up the whole message, and there will be no place for "n".

-Indexing from 1 to 2^128 won't work, as e.g., 2^128 will use up the whole message.

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If you want a unique 1:1 mapping to 2^128 elements, I can't see why an index of 2^128 wouldn't be the minimum. Is there some theory behind this that I'm missing? –  Roger Rowland May 27 '13 at 16:26