The theory is quite simple, but of course it takes some care to implement correctly.

You can choose any 16 bits anywhere in the message (including two bytes at the end or 16 individual bits scattered wherever you like) to be undefined. Call them *xi* for *i = 0..15*. Then use a bit-by-bit CRC algorithm to process the message, but generate and update the coefficients of 16 linear equations in *xi*, representing the 16 bits of the crc.

You then have a simple matrix equation *Ax + b = c*. The operations for *Ax + b = c* are not the usual multiplication and addition, but rather single-bit *and* and *exclusive-or* operations.

Now you use the usual methods to invert the matrix *A*, which is actually easier with *and* and *xor* (addition and subtraction are now both the same thing, just exclusive-or), compute *b ^ c* and multiply that by the inverse. Now you have the values to put in the *xi* bits to get the desired crc.

An additional simplification is that you don't need the actual message, just the length and the location of the *xi*, and then do the above with all the other bits of the message set to zero. This is because if you have two messages *P* and *Q* of the same length, then *crc(P) ^ crc(Q) = crc(P ^ Q)*. (This applies for the core crc algorithm, ignoring pre and post-processing of the crc.)

**Update:**

You can download spoof.c, which solves the problem of modifying a message to produce a particular CRC.

`The presented methods offer a very easy and efficient way to modify your data so that it will compute to a CRC you want or at least know in advance. This is not a very difficult task, as CRC is not a cryptographical hash algorithm [...] So you should never consider the CRC as some kind of message authentication code [...] – it can easily be forged.`

– Alexey Frunze Jul 25 '12 at 15:31