The Lucas-Lehmer primality test tests prime numbers to determine whether they are also Mersenne primes. One of the bottlenecks is the modulus operation in the calculation of `(s**2 − 2) % (2**p - 1)`

.

Using bitwise operations can speed things up considerably (see the L-L link), the best I have so far being:

```
def mod(n,p):
""" Returns the value of (s**2 - 2) % (2**p -1)"""
Mp = (1<<p) - 1
while n.bit_length() > p: # For Python < 2.7 use len(bin(n)) - 2 > p
n = (n & Mp) + (n >> p)
if n == Mp:
return 0
else:
return n
```

A simple test case is where `p`

has 5-9 digits and `s`

has 10,000+ digits (or more; not important what they are). Solutions can be tested by `mod((s**2 - 2), p) == (s**2 - 2) % (2**p -1)`

. Keep in mind that p - 2 iterations of this modulus operation are required in the L-L test, each with exponentially increasing `s`

, hence the need for optimization.

Is there a way to speed this up further, using pure Python (Python 3 included)? Is there a better way?

`while n > Mp:`

, which worked (although I can't understand why) and was faster. – Benjamin Mar 22 '11 at 16:01