mirror of
https://github.com/hastagAB/Awesome-Python-Scripts.git
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db9217b0cb
* Added an indepedent RSA library Added an indepedent RSA library with no depedences (adapted to communication) * Created README.md Created README.md * Update README.md * Added project to README.md Added project "Independent RSA Communication Algorithm" to README.md Co-authored-by: Ayush Bhardwaj <classicayush@gmail.com>
159 lines
4.6 KiB
Python
159 lines
4.6 KiB
Python
#Modulus (N) bit length, k.
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#OUTPUT: An RSA key pair ((N,e),d) where N is the modulus, the product of two primes (N=pq) not exceeding k bits in length;
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# e is the public exponent, a number less than and coprime to (p−1)(q−1);
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# and d is the private exponent such that e*d ≡ 1 mod (p−1)*(q−1).
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##############################################################
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#Select a value of e from 3,5,17,257,65537 (easy operations)
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# while p mod e = 1
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# p = genprime(k/2)
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#
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# while q mode e = 1:
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# q = genprime(k - k/2)
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#
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#N = p*q
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#L = (p-1)(q-1)
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#d = modinv(e, L)
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#return (N,e,d)
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from random import randrange, getrandbits
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import base64
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class rsa():
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def __init__(self, e=4, k=5):
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self.e = [3, 5, 17, 257, 65537][e]
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self.k = [128, 256, 1024, 2048, 3072, 4096][k]
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def is_prime(self, n, tests=128):
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if n == 2 or n == 3:
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return True
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if n <= 1 or n % 2 == 0:
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return False
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s = 0
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r = n - 1
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while r & 1 == 0:
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s += 1
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r //= 2
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for _ in range(tests):
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a = randrange(2, n - 1)
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x = pow(a, r, n)
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if x != 1 and x != n - 1:
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j = 1
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while j < s and x != n - 1:
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x = pow(x, 2, n)
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if x == 1:
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return False
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j += 1
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if x != n - 1:
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return False
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return True
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def genprime(self, length=1024):
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p = 1
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while len(bin(p))-2 != length:
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p = list(bin(getrandbits(length)))
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p = int(''.join(p[0:2] + ['1', '1'] + p[4:]), 2)
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p += 1 if p % 2 == 0 else 0
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ip = self.is_prime(p)
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while not ip:
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p += 2
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ip = self.is_prime(p)
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return p
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def egcd(self, a, b):
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if a == 0:
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return (b, 0, 1)
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else:
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g, y, x = self.egcd(b % a, a)
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return (g, x - (b // a) * y, y)
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def modinv(self, a, m):
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g, x, y = self.egcd(a, m)
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if g != 1:
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raise Exception('modular inverse does not exist')
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else:
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return x % m
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def get_creds(self, e, k):
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N = 0
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while len(bin(int(N)))-2 != k:
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p = self.genprime(int(k/2))
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while pow(p, 1, e) == 1:
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p = self.genprime(int(k/2))
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q = self.genprime(k - int(k/2))
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while pow(q, 1, e) == 1 and q == p:
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q = self.genprime(k - int(k/2))
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N = p*q
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L = (p-1)*(q-1)
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d = self.modinv(e, L)
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return p, q, (d, e, N)
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def get_keys(self):
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p, q, creds = self.get_creds(self.e, self.k)
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return creds
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def save_keys(self, filename="keys.k"):
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keys = self.get_keys()
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with open(filename, "w", encoding="utf-8") as file:
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file.write(str(keys[0]) + "\n" + str(keys[1]) + "\n" + str(keys[2]))
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def load_keys(self, filename="keys.k"):
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with open(filename, "r", encoding="utf-8") as file:
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f = file.read().split("\n")
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d = int(f[0])
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e = int(f[1])
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n = int(f[2])
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return (d, e, n)
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def encrypt(self, ke, plaintext):
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key, n = ke
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b64_string = base64.b64encode(plaintext.encode("utf-8")).decode("utf-8")
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ready_code = []
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for char in list(b64_string):
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ready_code.append('0' * (3 - len(str(ord(char)))) + str(ord(char)))
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ready_code = int("1" + "".join(ready_code))
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cipher = pow(ready_code, key, n)
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return cipher
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def decrypt(self, kd, ciphertext):
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key, n = kd
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plain_list = list(str(pow(ciphertext, key, n)))[1:]
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plain = []
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count = 1
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temp = ""
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for i in plain_list:
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if count != 4:
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temp += i
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count += 1
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else:
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plain.append(temp)
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temp = i
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count = 2
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plain.append(temp)
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plain_list = plain
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plain = base64.b64decode(''.join([chr(int(char)) for char in plain_list])).decode("utf-8")
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return plain
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encryption = rsa()
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keys = encryption.get_keys()
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d = keys[0]
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e = keys[1]
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n = keys[2]
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print("key: \n" + str(e) + "/" + str(n))
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while True:
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choose = input("Encrypt (e)/ Decrypt (d) > ")
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if choose == "e":
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e, n = input("insert key > ").split("/")
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to_encrypt = input("message to encrypt > ")
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a = encryption.encrypt((int(e), int(n)), to_encrypt)
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print(a)
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elif choose == "d":
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to_decrypt = input("message to decrypt > ")
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a = encryption.decrypt((d, n), to_decrypt)
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print(a)
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