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__init__.py	1.57 KB	-rw-r--r--	2022-07-20 10:28
asn1.py	1.75 KB	-rw-r--r--	2021-03-29 21:17
cli.py	9.94 KB	-rw-r--r--	2021-11-24 09:39
common.py	4.75 KB	-rw-r--r--	2021-11-24 10:00
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transform.py	2.22 KB	-rw-r--r--	2021-11-24 10:00
util.py	3.02 KB	-rw-r--r--	2021-03-29 21:17

Rename

#  Copyright 2011 Sybren A. Stüvel <sybren@stuvel.eu>
#
#  Licensed under the Apache License, Version 2.0 (the "License");
#  you may not use this file except in compliance with the License.
#  You may obtain a copy of the License at
#
#      https://www.apache.org/licenses/LICENSE-2.0
#
#  Unless required by applicable law or agreed to in writing, software
#  distributed under the License is distributed on an "AS IS" BASIS,
#  WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
#  See the License for the specific language governing permissions and
#  limitations under the License.

"""Numerical functions related to primes.

Implementation based on the book Algorithm Design by Michael T. Goodrich and
Roberto Tamassia, 2002.
"""

import rsa.common
import rsa.randnum

__all__ = ["getprime", "are_relatively_prime"]

def gcd(p: int, q: int) -> int:
    """Returns the greatest common divisor of p and q

>>> gcd(48, 180)
    12
    """

while q != 0:
        (p, q) = (q, p % q)
    return p

def get_primality_testing_rounds(number: int) -> int:
    """Returns minimum number of rounds for Miller-Rabing primality testing,
    based on number bitsize.

According to NIST FIPS 186-4, Appendix C, Table C.3, minimum number of
    rounds of M-R testing, using an error probability of 2 ** (-100), for
    different p, q bitsizes are:
      * p, q bitsize: 512; rounds: 7
      * p, q bitsize: 1024; rounds: 4
      * p, q bitsize: 1536; rounds: 3
    See: http://nvlpubs.nist.gov/nistpubs/FIPS/NIST.FIPS.186-4.pdf
    """

# Calculate number bitsize.
    bitsize = rsa.common.bit_size(number)
    # Set number of rounds.
    if bitsize >= 1536:
        return 3
    if bitsize >= 1024:
        return 4
    if bitsize >= 512:
        return 7
    # For smaller bitsizes, set arbitrary number of rounds.
    return 10

def miller_rabin_primality_testing(n: int, k: int) -> bool:
    """Calculates whether n is composite (which is always correct) or prime
    (which theoretically is incorrect with error probability 4**-k), by
    applying Miller-Rabin primality testing.

For reference and implementation example, see:
    https://en.wikipedia.org/wiki/Miller%E2%80%93Rabin_primality_test

:param n: Integer to be tested for primality.
    :type n: int
    :param k: Number of rounds (witnesses) of Miller-Rabin testing.
    :type k: int
    :return: False if the number is composite, True if it's probably prime.
    :rtype: bool
    """

# prevent potential infinite loop when d = 0
    if n < 2:
        return False

# Decompose (n - 1) to write it as (2 ** r) * d
    # While d is even, divide it by 2 and increase the exponent.
    d = n - 1
    r = 0

while not (d & 1):
        r += 1
        d >>= 1

# Test k witnesses.
    for _ in range(k):
        # Generate random integer a, where 2 <= a <= (n - 2)
        a = rsa.randnum.randint(n - 3) + 1

x = pow(a, d, n)
        if x == 1 or x == n - 1:
            continue

for _ in range(r - 1):
            x = pow(x, 2, n)
            if x == 1:
                # n is composite.
                return False
            if x == n - 1:
                # Exit inner loop and continue with next witness.
                break
        else:
            # If loop doesn't break, n is composite.
            return False

return True

def is_prime(number: int) -> bool:
    """Returns True if the number is prime, and False otherwise.

>>> is_prime(2)
    True
    >>> is_prime(42)
    False
    >>> is_prime(41)
    True
    """

# Check for small numbers.
    if number < 10:
        return number in {2, 3, 5, 7}

# Check for even numbers.
    if not (number & 1):
        return False

# Calculate minimum number of rounds.
    k = get_primality_testing_rounds(number)

# Run primality testing with (minimum + 1) rounds.
    return miller_rabin_primality_testing(number, k + 1)

def getprime(nbits: int) -> int:
    """Returns a prime number that can be stored in 'nbits' bits.

>>> p = getprime(128)
    >>> is_prime(p-1)
    False
    >>> is_prime(p)
    True
    >>> is_prime(p+1)
    False

>>> from rsa import common
    >>> common.bit_size(p) == 128
    True
    """

assert nbits > 3  # the loop will hang on too small numbers

while True:
        integer = rsa.randnum.read_random_odd_int(nbits)

# Test for primeness
        if is_prime(integer):
            return integer

# Retry if not prime

def are_relatively_prime(a: int, b: int) -> bool:
    """Returns True if a and b are relatively prime, and False if they
    are not.

>>> are_relatively_prime(2, 3)
    True
    >>> are_relatively_prime(2, 4)
    False
    """

d = gcd(a, b)
    return d == 1

if __name__ == "__main__":
    print("Running doctests 1000x or until failure")
    import doctest

for count in range(1000):
        (failures, tests) = doctest.testmod()
        if failures:
            break

if count % 100 == 0 and count:
            print("%i times" % count)

print("Doctests done")