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RSA Explained in Python
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#!/usr/bin/env python | |
# This example demonstrates RSA public-key cryptography in an | |
# easy-to-follow manner. It works on integers alone, and uses much smaller numbers | |
# for the sake of clarity. | |
##################################################################### | |
# First we pick our primes. These will determine our keys. | |
##################################################################### | |
# Pick P,Q,and E such that: | |
# 1: P and Q are prime; picked at random. | |
# 2: 1 < E < (P-1)*(Q-1) and E is co-prime with (P-1)*(Q-1) | |
P=97 # First prime | |
Q=83 # Second prime | |
E=53 # usually a constant; 0x10001 is common, prime is best | |
##################################################################### | |
# Next, some functions we'll need in a moment: | |
##################################################################### | |
# Note on what these operators do: | |
# % is the modulus (remainder) operator: 10 % 3 is 1 | |
# // is integer (round-down) division: 10 // 3 is 3 | |
# ** is exponent (2**3 is 2 to the 3rd power) | |
# Brute-force (i.e. try every possibility) primality test. | |
def isPrime(x): | |
if x%2==0 and x>2: return False # False for all even numbers | |
i=3 # we don't divide by 1 or 2 | |
sqrt=x**.5 | |
while i<sqrt: | |
if x%i==0: return False | |
i+=2 | |
return True | |
# Part of find_inverse below | |
# See: http://en.wikipedia.org/wiki/Extended_Euclidean_algorithm | |
def eea(a,b): | |
if b==0:return (1,0) | |
(q,r) = (a//b,a%b) | |
(s,t) = eea(b,r) | |
return (t, s-(q*t) ) | |
# Find the multiplicative inverse of x (mod y) | |
# see: http://en.wikipedia.org/wiki/Modular_multiplicative_inverse | |
def find_inverse(x,y): | |
inv = eea(x,y)[0] | |
if inv < 1: inv += y #we only want positive values | |
return inv | |
##################################################################### | |
# Make sure the numbers we picked above are valid. | |
##################################################################### | |
if not isPrime(P): raise Exception("P (%i) is not prime" % (P,)) | |
if not isPrime(Q): raise Exception("Q (%i) is not prime" % (Q,)) | |
T=(P-1)*(Q-1) # Euler's totient (intermediate result) | |
# Assuming E is prime, we just have to check against T | |
if E<1 or E > T: raise Exception("E must be > 1 and < T") | |
if T%E==0: raise Exception("E is not coprime with T") | |
##################################################################### | |
# Now that we've validated our random numbers, we derive our keys. | |
##################################################################### | |
# Product of P and Q is our modulus; the part determines as the "key size". | |
MOD=P*Q | |
# Private exponent is inverse of public exponent with respect to (mod T) | |
D = find_inverse(E,T) | |
# The modulus is always needed, while either E or D is the exponent, depending on | |
# which key we're using. D is much harder for an adversary to derive, so we call | |
# that one the "private" key. | |
print "public key: (MOD: %i, E: %i)" % (MOD,E) | |
print "private key: (MOD: %i, D: %i)" % (MOD,D) | |
# Note that P, Q, and T can now be discarded, but they're usually | |
# kept around so that a more efficient encryption algorithm can be used. | |
# http://en.wikipedia.org/wiki/RSA#Using_the_Chinese_remainder_algorithm | |
##################################################################### | |
# We have our keys, let's do some encryption | |
##################################################################### | |
# Here I only focus on whether you're applying the private key or | |
# applying the public key, since either one will reverse the other. | |
import sys | |
print "Enter \">NUMBER\" to apply private key and \"<NUMBER\" to apply public key; \"Q\" to quit." | |
while True: | |
sys.stdout.write("? ") | |
line=sys.stdin.readline().strip() | |
if not line: break | |
if line=='q' or line=='Q': break | |
if line[0]=='<': key = E | |
elif line[0]=='>': key = D | |
else: | |
print "Must start with either < or >" | |
print "Enter \">NUMBER\" to apply private key and \"<NUMBER\" to apply public key; \"Q\" to quit." | |
continue | |
line=line[1:] | |
try: before=int(line) | |
except ValueError: | |
print "not a number: \"%s\"" % (line) | |
print "Enter \">NUMBER\" to apply private key and \"<NUMBER\" to apply public key; \"Q\" to quit." | |
continue | |
if before >= MOD: | |
print "Only values up to %i can be encoded with this key (choose bigger primes next time)" % (MOD,) | |
continue | |
# Note that the pow() built-in does modulo exponentation. That's handy, since it saves us having to | |
# implement that ablity. | |
# http://en.wikipedia.org/wiki/Modular_exponentiation | |
after = pow(before,key,MOD) #encrypt/decrypt using this ONE command. Surprisingly simple. | |
if key == D: print "PRIVATE(%i) >> %i" %(before,after) | |
else: print "PUBLIC(%i) >> %i" %(before,after) |
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