src/third_party/mozjs-45/python/PyECC/ecc/primes.py - cobalt - Git at Google

 '''
 This module implements simple prime generation and primality testing.
 '''

 from random import SystemRandom
 random = SystemRandom()
 from os import urandom

 def exp(x, n, m):
     '''Efficiently compute x ** n mod m'''
     y = 1
     z = x
     while n > 0:
         if n & 1:
             y = (y * z) % m
         z = (z * z) % m
         n //= 2
     return y


 # Miller-Rabin-Test

 def prime(n, k):
     '''Checks whether n is probably prime (with probability 1 - 4**(-k)'''

     if n % 2 == 0:
         return False

     d = n - 1
     s = 0

     while d % 2 == 0:
         s += 1
         d /= 2

     for i in xrange(k):

         a = long(2 + random.randint(0, n - 4))
         x = exp(a, d, n)
         if (x == 1) or (x == n - 1):
             continue

         for r in xrange(1, s):
             x = (x * x) % n

             if x == 1:
                 return False

             if x == n - 1:
                 break

         else:
             return False
     return True


 # Generate and Test Algorithms

 def get_prime(size, accuracy):
     '''Generate a pseudorandom prime number with the specified size (bytes).'''

     while 1:

         # read some random data from the operating system
         rstr = urandom(size - 1)
         r = 128 | ord(urandom(1))   # MSB = 1 (not less than size)
         for c in rstr:
             r = (r << 8) | ord(c)
         r |= 1                      # LSB = 1 (odd)

         # test whether this results in a prime number
         if prime(r, accuracy):
             return r


 def get_prime_upto(n, accuracy):
     '''Find largest prime less than n'''
     n |= 1
     while n > 0:
         n -= 2
         if prime(n, accuracy):
             return n
	'''
	This module implements simple prime generation and primality testing.
	'''

	from random import SystemRandom
	random = SystemRandom()
	from os import urandom

	def exp(x, n, m):
	'''Efficiently compute x ** n mod m'''
	y = 1
	z = x
	while n > 0:
	if n & 1:
	y = (y * z) % m
	z = (z * z) % m
	n //= 2
	return y


	# Miller-Rabin-Test

	def prime(n, k):
	'''Checks whether n is probably prime (with probability 1 - 4**(-k)'''

	if n % 2 == 0:
	return False

	d = n - 1
	s = 0

	while d % 2 == 0:
	s += 1
	d /= 2

	for i in xrange(k):

	a = long(2 + random.randint(0, n - 4))
	x = exp(a, d, n)
	if (x == 1) or (x == n - 1):
	continue

	for r in xrange(1, s):
	x = (x * x) % n

	if x == 1:
	return False

	if x == n - 1:
	break

	else:
	return False
	return True


	# Generate and Test Algorithms

	def get_prime(size, accuracy):
	'''Generate a pseudorandom prime number with the specified size (bytes).'''

	while 1:

	# read some random data from the operating system
	rstr = urandom(size - 1)
	r = 128 \| ord(urandom(1)) # MSB = 1 (not less than size)
	for c in rstr:
	r = (r << 8) \| ord(c)
	r \|= 1 # LSB = 1 (odd)

	# test whether this results in a prime number
	if prime(r, accuracy):
	return r


	def get_prime_upto(n, accuracy):
	'''Find largest prime less than n'''
	n \|= 1
	while n > 0:
	n -= 2
	if prime(n, accuracy):
	return n