# How to implement Frobenius pseudoprime algorithm?

Someone told me that the Frobenius pseudoprime algorithm take three times longer to run than the Miller–Rabin primality test but has seven times the resolution. So then if one where to run the former ten times and the later thirty times, both would take the same time to run, but the former would provide about 233% more analyse power. In trying to find out how to perform the test, the following paper was discovered with the algorithm at the end:

A Simple Derivation for the Frobenius Pseudoprime Test

There is an attempt at implementing the algorithm below, but the program never prints out a number. Could someone who is more familiar with the math notation or algorithm verify what is going on please?

Edit 1: The code below has corrections added, but the implementation for `compute_wm_wm1` is missing. Could someone explain the recursive definition from an algorithmic standpoint? It is not "clicking" for me.

Edit 2: The erroneous code has been removed, and an implementation of the `compute_wm_wm1` function has been added below. It appears to work but may require further optimization to be practical.

``````from random import SystemRandom
from fractions import gcd
random = SystemRandom().randrange

def find_prime_number(bits, test):
number = random((1 << bits - 1) + 1, 1 << bits, 2)
while True:
for _ in range(test):
if not frobenius_pseudoprime(number):
break
else:
return number
number += 2

def frobenius_pseudoprime(integer):
assert integer & 1 and integer >= 3
a, b, d = choose_ab(integer)
w1 = (a ** 2 * extended_gcd(b, integer)[0] - 2) % integer
m = (integer - jacobi_symbol(d, integer)) >> 1
wm, wm1 = compute_wm_wm1(w1, m, integer)
if w1 * wm != 2 * wm1 % integer:
return False
b = pow(b, (integer - 1) >> 1, integer)
return b * wm % integer == 2

def choose_ab(integer):
a, b = random(1, integer), random(1, integer)
d = a ** 2 - 4 * b
while is_square(d) or gcd(2 * d * a * b, integer) != 1:
a, b = random(1, integer), random(1, integer)
d = a ** 2 - 4 * b
return a, b, d

def is_square(integer):
if integer < 0:
return False
if integer < 2:
return True
x = integer >> 1
seen = set([x])
while x * x != integer:
x = (x + integer // x) >> 1
if x in seen:
return False
return True

def extended_gcd(n, d):
x1, x2, y1, y2 = 0, 1, 1, 0
while d:
n, (q, d) = d, divmod(n, d)
x1, x2, y1, y2 = x2 - q * x1, x1, y2 - q * y1, y1
return x2, y2

def jacobi_symbol(n, d):
j = 1
while n:
while not n & 1:
n >>= 1
if d & 7 in {3, 5}:
j = -j
n, d = d, n
if n & 3 == 3 == d & 3:
j = -j
n %= d
return j if d == 1 else 0

def compute_wm_wm1(w1, m, n):
a, b = 2, w1
for shift in range(m.bit_length() - 1, -1, -1):
if m >> shift & 1:
a, b = (a * b - w1) % n, (b * b - 2) % n
else:
a, b = (a * a - 2) % n, (a * b - w1) % n
return a, b

print('Probably prime:\n', find_prime_number(300, 10))
``````
-

You seem to have misunderstood the algorithm completely due to not being familiar with the notation.

``````def frobenius_pseudoprime(integer):
assert integer & 1 and integer >= 3
a, b, d = choose_ab(integer)
w1 = (a ** 2 // b - 2) % integer
``````

That comes from the line

W0 ≡ 2 (mod n) and W1 ≡ a2b−1 − 2 (mod n)

But the b-1 doesn't mean `1/b` here, but the modular inverse of `b` modulo `n`, i.e. an integer `c` with `b·c ≡ 1 (mod n)`. You can most easily find such a `c` by continued fraction expansion of `b/n` or, equivalently, but with slightly more computation, by the extended Euclidean algorithm. Since you're probably not familiar with continued fractions, I recommend the latter.

``````    m = (integer - d // integer) // 2
``````

comes from

n − (∆/n) = 2m

and misunderstands the Jacobi symbol as a fraction/division (admittedly, I have displayed it here even more like a fraction, but since the site doesn't support LaTeX rendering, we'll have to make do). The Jacobi symbol is a generalisation of the Legendre symbol - denoted identically - which indicates whether a number is a quadratic residue modulo an odd prime (if `n` is a quadratic residue modulo `p`, i.e. there is a `k` with `k^2 ≡ n (mod p)` and `n` is not a multiple of `p`, then `(n/p) = 1`, if `n` is a multiple of `p`, then `(n/p) = 0`, otherwise `(n/p) = -1`). The Jacobi symbol lifts the restriction that the 'denominator' be an odd prime and allows arbitrary odd numbers as 'denominators'. Its value is the product of the Legendre symbols with the same 'numerator' for all primes dividing `n` (according to multiplicity). More on that, and how to compute Jacobi symbols efficiently in the linked article. The line should correctly read

``````m = (integer - jacobi_symbol(d,integer)) // 2
``````

The following lines I completely fail to understand, logically, here should follow the calculation of Wm and Wm+1 using the recursion

W2j ≡ Wj2 − 2 (mod n)

W2j+1 ≡ WjWj+1 − W1 (mod n)

An efficient method of using that recursion to compute the required values is given around formula (11) of the PDF.

``````    w_m0 = w1 * 2 // m % integer
w_m1 = w1 * 2 // (m + 1) % integer
w_m2 = (w_m0 * w_m1 - w1) % integer
``````

The remainder of the function is almost correct, except of course that it now gets the wrong data due to earlier misunderstandings.

``````    if w1 * w_m0 != 2 * w_m2:
``````

The (in)equality here should be modulo `integer`, namely `if (w1*w_m0 - 2*w_m2) % integer != 0`.

``````        return False
b = pow(b, (integer - 1) // 2, integer)
return b * w_m0 % integer == 2
``````

Note, however, that if `n` is a prime, then

``````b^((n-1)/2) ≡ (b/n) (mod n)
``````

where `(b/n)` is the Legendre (or Jacobi) symbol (for prime 'denominators', the Jacobi symbol is the Legendre symbol), hence `b^((n-1)/2) ≡ ±1 (mod n)`. So you could use that as an extra check, if Wm is not 2 or `n-2`, `n` can't be prime, nor can it be if `b^((n-1)/2) (mod n)` is not 1 or `n-1`.

Probably computing `b^((n-1)/2) (mod n)` first and checking whether that's 1 or `n-1` is a good idea, since if that check fails (that is the Euler pseudoprime test, by the way) you don't need the other, no less expensive, computations anymore, and if it succeeds, it's very likely that you need to compute it anyway.

Regarding the corrections, they seem correct, except for one that made a glitch I previously overlooked possibly worse:

``````if w1 * wm != 2 * wm1 % integer:
``````

That applies the modulus only to `2 * wm1`.

Concerning the recursion for the Wj, I think it is best to explain with a working implementation, first in toto for easy copy and paste:

``````def compute_wm_wm1(w1,m,n):
a, b = 2, w1
bits = int(log(m,2)) - 2
if bits < 0:
bits = 0
if (mask & m) != 0:
a, b = (a*b-w1)%n, (b*b-2)%n
else:
a, b = (a*a-2)%n, (a*b-w1)%n
return a, b
``````

Then with explanations in between:

``````def compute_wm_wm1(w1,m,n):
``````

We need the value of W1, the index of the desired number, and the number by which to take the modulus as input. The value W0 is always 2, so we don't need that as a parameter.

Call it as

``````wm, wm1 = compute_wm_wm1(w1,m,integer)
``````

in `frobenius_pseudoprime` (aside: not a good name, most of the numbers returning `True` are real primes).

``````    a, b = 2, w1
``````

We initialise `a` and `b` to W0 and W1 respectively. At each point, `a` holds the value of Wj and `b` the value of Wj+1, where `j` is the value of the bits of `m` so far consumed. For example, with `m = 13`, the values of `j`, `a` and `b` develop as follows:

``````consumed remaining  j    a    b
1101     0   w_0  w_1
1        101     1   w_1  w_2
11        01     3   w_3  w_4
110        1     6   w_6  w_7
1101            13  w_13  w_14
``````

The bits are consumed left-to-right, so we have to find the first set bit of `m` and place our 'pointer' right before it

``````    bits = int(log(m,2)) - 2
if bits < 0:
bits = 0
``````

I subtracted a bit from the computed logarithm just to be entirely sure that we don't get fooled by a floating point error (by the way, using `log` limits you to numbers of at most 1024 bits, about 308 decimal digits; if you want to treat larger numbers, you have to find the base-2 logarithm of `m` in a different way, using `log` was the simplest way, and it's just a proof of concept, so I used that here).

``````    while mask <= m:
``````

Shift the mask until it's greater than `m`,so the set bit points just before `m`'s first set bit. Then shift one position back, so we point at the bit.

``````    mask >>= 1
if (mask & m) != 0:
a, b = (a*b-w1)%n, (b*b-2)%n
``````

If the next bit is set, the value of the initial portion of consumed bits of `m` goes from `j` to `2*j+1`, so the next values of the W sequence we need are W2j+1 for `a` and W2j+2 for `b`. By the above recursion formula,

``````W_{2j+1} = W_j * W_{j+1} - W_1 (mod n)
W_{2j+2} = W_{j+1}^2 - 2 (mod n)
``````

Since `a` was Wj and `b` was Wj+1, `a` becomes `(a*b - W_1) % n` and `b` becomes `(b * b - 2) % n`.

``````        else:
a, b = (a*a-2)%n, (a*b-w1)%n
``````

If the next bit is not set, the value of the initial portion of consumed bits of `m` goes from `j` to `2*j`, so `a` becomes W2j = (Wj2 - 2) (mod n), and `b` becomes W2j+1 = (Wj * Wj+1 - W1) (mod n).

``````        mask >>= 1
``````

Move the pointer to the next bit. When we have moved past the final bit, `mask` becomes 0 and the loop ends. The initial portion of consumed bits of `m` is now all of `m`'s bits, so the value is of course `m`. Then we can

``````    return a, b
``````

``````def find_prime_number(bits, test):
while True:
number = random(3, 1 << bits, 2)
for _ in range(test):
if not frobenius_pseudoprime(number):
break
else:
return number
``````

Primes are not too frequent among the larger numbers, so just picking random numbers is likely to take a lot of attempts to hit one. You will probably find a prime (or probable prime) faster if you pick one random number and check candidates in order.

Another point is that such a test as the Frobenius test is disproportionally expensive to find that e.g. a multiple of 3 is composite. Before using such a test (or a Miller-Rabin test, or a Lucas test, or an Euler test, ...), you should definitely do a bit of trial division to weed out most of the composites and do the work only where it has a fighting chance of being worth it.

Oh, and the `is_square` function isn't prepared to deal with arguments less than 2, divide-by-zero errors lurk there,

``````def is_square(integer):
if integer < 0:
return False
if integer < 2:
return True
x = integer // 2
``````

should help.

-
Interesting, as a maths noob I make these sort of mistakes a lot. Do mathematicians make the symbols ambiguous just for laughs?? –  Peter Wishart May 18 '12 at 20:49
Thank you for your insight! Would you mind looking over the corrections and possibly explain those recursive definitions? Reading the method near formula (11) left me confused. –  Noctis Skytower May 18 '12 at 21:03
@NoctisSkytower Explanation (and working code) added. –  Daniel Fischer May 18 '12 at 23:08
@PeterWishart No, the symbols are not made ambiguous just for laughs. The supply of symbols used to be very limited (it still is, though less so) for printing, so the symbols got reused. Also, it is not easy to come up with new symbols for every new concept. While the communication was exclusively between insiders, one could rely on the audience being able to discern the meaning from the context, so traditionally, there was little incentive to avoid duplication of meaning. –  Daniel Fischer May 18 '12 at 23:16
Thank you for all your help, Mr. Fischer! Your `compute_wm_wm1` was rewritten to be somewhat shorter than the original. The solution as a whole is probably not perfect, but it seems to work based on your assistance. –  Noctis Skytower May 21 '12 at 13:56