Since I was looking for a LFSR-implementation in Python, I stumbled upon this topic. I found however that the following was a bit more accurate according to my needs:

```
def lfsr(seed, mask):
result = seed
nbits = mask.bit_length()-1
while True:
result = (result << 1)
xor = result >> nbits
if xor != 0:
result ^= mask
yield xor, result
```

The above LFSR-generator is based on GF(2^{k}) modulus calculus (GF = Galois Field). Having just completed an Algebra course, I'm going to explain this the mathematical way.

Let's start by taking, for example, GF(2^{4}), which equals to {a_{4}x^{4} + a_{3}x^{3} + a_{2}x^{2} + a_{1}x^{1} + a_{0}x^{0} | a_{0}, a_{1}, ..., a_{4} ∈ Z_{2}} (to clarify, Z_{n} = {0,1,...,n-1} and therefore Z_{2} = {0,1}, i.e. one bit). This means that this is the set of all polynomials of the fourth degree with all factors either being present or not, but having no multiples of these factors (e.g. there's no 2x^{k}). x^{3}, x^{4} + x^{3}, 1 and x^{4} + x^{3} + x^{2} + x + 1 are all examples of members of this group.

We take this set modulus a polynomial of the fourth degree (i.e., P(x) ∈ GF(2^{4})), e.g. P(x) = x^{4}+x^{1}+x^{0}. This modulus operation on a group is also denoted as GF(2^{4}) / P(x). For your reference, P(x) describes the 'taps' within the LFSR.

We also take a random polynomial of degree 3 or lower (so that it's not affected by our modulus, otherwise we could just as well perform the modulus operation directly on it), e.g. A_{0}(x) = x^{0}. Now every subsequent A_{i}(x) is calculated by multiplying it with x: A_{i}(x) = A_{i-1}(x) * x mod P(x).

Since we are in a limited field, the modulus operation may have an effect, but only when the resulting A_{i}(x) has at least a factor x^{4} (our highest factor in P(x)). Note that, since we are working with numbers in Z_{2}, performing the modulus operation itself is nothing more than determining whether every a_{i} becomes a 0 or 1 by adding the two values from P(x) and A_{i}(x) together (i.e., 0+0=0, 0+1=1, 1+1=0, or 'xoring' these two).

Every polynomial can be written as a set of bits, for example x^{4}+x^{1}+x^{0} ~ 10011. The A_{0}(x) can be seen as the seed. The 'times x' operation can be seen as a shift left operation. The modulus operation can be seen as a bit masking operation, with the mask being our P(x).

The algorithm depicted above therefore generates (an infinite stream of) valid four bit LFSR patterns. For example, for our defined A_{0}(x) *(x*^{0}) and P(x) *(x*^{4}+x^{1}+x^{0}), we can define the following first yielded results in GF(2^{4}) (note that A_{0} is not yielded until at the end of the first round -- mathematicians generally start counting at '1'):

```
i Ai(x) 'x⁴' bit pattern
0 0x³ + 0x² + 0x¹ + 1x⁰ 0 0001 (not yielded)
1 0x³ + 0x² + 1x¹ + 0x⁰ 0 0010
2 0x³ + 1x² + 0x¹ + 0x⁰ 0 0100
3 1x³ + 0x² + 0x¹ + 0x⁰ 0 1000
4 0x³ + 0x² + 1x¹ + 1x⁰ 1 0011 (first time we 'overflow')
5 0x³ + 1x² + 1x¹ + 0x⁰ 0 0110
6 1x³ + 1x² + 0x¹ + 0x⁰ 0 1100
7 1x³ + 0x² + 1x¹ + 1x⁰ 1 1011
8 0x³ + 1x² + 0x¹ + 1x⁰ 1 0101
9 1x³ + 0x² + 1x¹ + 0x⁰ 0 1010
10 0x³ + 1x² + 1x¹ + 1x⁰ 1 0111
11 1x³ + 1x² + 1x¹ + 0x⁰ 0 1110
12 1x³ + 1x² + 1x¹ + 1x⁰ 1 1111
13 1x³ + 1x² + 0x¹ + 1x⁰ 1 1101
14 1x³ + 0x² + 0x¹ + 1x⁰ 1 1001
15 0x³ + 0x² + 0x¹ + 1x⁰ 1 0001 (same as i=0)
```

Note that your mask must contain a '1' at the fourth position to make sure that your LFSR generates four-bit results. Also note that a '1' must be present at the zeroth position to make sure that your bitstream would not end up with a 0000 bit pattern, or that the final bit would become unused (if all bits are shifted to the left, you would also end up with a zero at the 0th position after one shift).

Not all P(x)'s necessarily are generators for GF(2^{k}) (i.e., not all masks of k bits generate all 2^{k-1}-1 numbers). For example, x^{4} + x^{3} + x^{2} + x^{1} + x^{0} generates 3 groups of 5 distinct polynomals each, or "3 cycles of period 5": 0001,0010,0100,1000,1111; 0011,0110,1100,0111,1110; and 0101,1010,1011,1001,1101. Note that 0000 can never be generated, and can't generate any other number.

Usually, the output of an LFSR is the bit that is 'shifted' out, which is a '1' if the modulus operation is performed, and a '0' when it isn't. LFSR's with a period of 2^{k-1}-1, also called pseudo-noise or PN-LFSR's, adhere to Golomb's randomness postulates, which says as much as that this output bit is random 'enough'.

Sequences of these bits therefore have their use in cryptography, for instance in the A5/1 and A5/2 mobile encryption standards, or the E0 Bluetooth standard. However, they are not as secure as one would like: the Berlekamp-Massey algorithm can be used to reverse-engineer the characteristic polynomal (the P(x)) of the LFSR. Strong encryption standards therefore use Non-linear FSR's or similar non-linear functions. A related topic to this are the S-Boxes used in AES.

*Note that I have used the *`int.bit_length()`

operation. This was not implemented until Python 2.7.

If you'd only like a finite bit pattern, you could check whether the seed equals the result and then break your loop.

You can use my LFSR-method in a for-loop (e.g. `for xor, pattern in lfsr(0b001,0b10011)`

) or you can repeatedly call the `.next()`

operation on the result of the method, returning a new `(xor, result)`

-pair everytime.