For small `M`

@user1494736 is right: just make a lookup table that happens to be bijective, and tailor it to your needs.

For large `M`

storing the table becomes impractical; we need an algorithm to calculate the mapping. You mentioned we don't need strong cryptography; this frees us to choose something more light-weight than standard ciphers. That said, they are quite fast and I expect you could use one easily with a 3rd-party library. But let's suppose you prefer to avoid this for some reason.

One way to make a poor man's cipher is to `xor`

a constant onto your plaintext (to change the Hamming weight), and then apply a bit permutation (to destroy locality.) Both of these steps are invertible. It sounds like you want to display your cipher letters as ASCII. So, we may want a final invertible transform (an addition) to ensure the cipher values are printable.

You mentioned `M`

might be as large as a few million. So, let's take your plaintext letters (and so ciphertext letters) to be 32-bit values. Finding a random 32-bit value to `xor`

is easy. How about the bit permutation?

A few million plaintext letters translates into each letter being around `22`

or `23`

bits wide; this leaves at least `8`

(logical) upper bits cleared in every plaintext letter. The permutation can take advantage of this to help ensure the ciphertext bytes are within the ASCII printable range. By sending that upper plaintext byte to the upper two bits of each of the four cipher bytes, we ensure each cipher byte takes values `0`

to `63`

. The final step could then add `48`

to make the range `48`

to `111`

, well within the ASCII printable range.

Playing off this observation, we could envision our plaintext letter as a `4x4`

grid of bit pairs (hex digits), and make our permutation a rotation of this grid:

```
Plain
A B C D byte 3 (the high byte, expected to be all 0)
E F G H byte 2
I J K L byte 1
M N O P byte 0
Cipher
D H L P byte 3
C G K O byte 2
B F J N byte 1
A E I M byte 0
```

Or put another way:

```
Byte 3 2 1 0
Plain ABCD EFGH IJKL MNOP
Cipher DHLP CGKO BFJN AEIM
```

Notice that a piece of each plaintext byte appears in every ciphertext byte: this is what will ensure the encoding "looks random".

`M`

expected to be? 26, perhaps, or thousands? millions? – phs Aug 3 '12 at 4:32