As part of a school project I'm implementing some crypthographic algorithms in Haskell. As you probably know this involves quite a lot of low level bit fiddling. Now I am stuck on one particular sub routine which causes me a headache. The routine, which is a permutation on 256 bits, works as follows:

Input: a 256 bit block.

Then all the even numbered bits (0,2,...) in the input block are taken to be the first 128 bits in the output block. While the odd numbered bits are taken to be the 128 last bits in the output block. More specifically, the formula for the *i'th* bit in the output is given as (a_{i} is the *i'th* bit in the input block, and b is the output):

b

_{i}= a_{2i}b

_{i+2d-1}= a_{2i + 1}for

ifrom 0 to 2^{d-1}-1, d = 8.

As a toy example, assume we used a reduced version of the routine which worked with 16 bit blocks instead of 256 bits. Then the following bitstring would be permuted as follows:

1010 1010 1010 1010 -> 1111 1111 0000 0000

I have not been able to come up with a clean implementation for this function. In particular I have been trying with a ByteString -> ByteString signature, but that sort of forces me to work on a Word8 kind of granularity. But each byte in the output bytestring is a function of bits in all the other bytes, which requires some really messy operations.

I will be really grateful for any kind of hint or advice on how to approach this problem.