def __init__(self, key = None, padding = padWithPadLen(), keySize=16):
""" Initialize AES, keySize is in bytes """
if not (keySize == 16 or keySize == 24 or keySize == 32) :
raise BadKeySizeError, 'Illegal AES key size, must be 16, 24, or 32 bytes'
Rijndael.__init__( self, key, padding=padding, keySize=keySize, blockSize=16 )
self.name = 'AES'
def __init__(self, key = None, padding = padWithPadLen(), keySize=16):
""" Initialize AES, keySize is in bytes """
if not (keySize == 16 or keySize == 24 or keySize == 32) :
raise BadKeySizeError, 'Illegal AES key size, must be 16, 24, or 32 bytes'
Rijndael.__init__( self, key, padding=padding, keySize=keySize, blockSize=16 )
self.name = 'AES'
def testIVuniqueness(self):
""" Test that two different instances have different IVs """
key = a2b_p('2b7e151628aed2a6abf7158809cf4f3c')
pt = "This is a test case"
alg1 = CBC(Rijndael(key, blockSize=32))
alg2 = CBC(Rijndael(key, blockSize=32))
ct1 = alg1.encrypt(pt)
ct2 = alg2.encrypt(pt)
self.assertNotEqual(ct1, ct2)
def RijndaelTestVec(i, key, pt, ct):
""" Run single AES test vector with any legal blockSize
and any legal key size. """
bkey, plainText, cipherText = a2b_hex(key), a2b_hex(pt), a2b_hex(ct)
kSize = len(bkey)
bSize = len(cipherText) # set block size to length of block
alg = Rijndael(bkey, keySize=kSize, blockSize=bSize, padding=noPadding())
self.assertEqual( alg.encrypt(plainText), cipherText )
self.assertEqual( alg.decrypt(cipherText), plainText )
def RijndaelTestVec(i, key, pt, ct):
""" Run single AES test vector with any legal blockSize
and any legal key size. """
bkey, plainText, cipherText = a2b_hex(key), a2b_hex(pt), a2b_hex(
ct)
kSize = len(bkey)
bSize = len(cipherText) # set block size to length of block
alg = Rijndael(bkey,
keySize=kSize,
blockSize=bSize,
padding=noPadding())
self.assertEqual(alg.encrypt(plainText), cipherText)
self.assertEqual(alg.decrypt(cipherText), plainText)
def testIVmultencryptUnique(self):
""" Test that two different encrypts have different IVs """
key = a2b_p('2b7e151628aed2a6abf7158809cf4f3c')
pt = "This is yet another test case"
alg1 = CBC(Rijndael(key, blockSize=32))
ct1 = alg1.encrypt(pt)
ct2 = alg1.encrypt(pt)
self.assertNotEqual(ct1, ct2)
self.assertEqual(alg1.decrypt(ct1), pt)
self.assertEqual(alg1.decrypt(ct1), alg1.decrypt(ct2))
def testCBC_Rijndael_variable_data(self):
""" Rijndael CBC 256 """
key = '2b7e151628aed2a6abf7158809cf4f3c'
iv = '000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f'
key, iv = a2b_p(key), a2b_p(iv)
alg = CBC(Rijndael(key, blockSize=32))
for i in range(100):
pt = i * 'a'
ct = alg.encrypt(pt, iv=iv)
self.assertEqual(alg.decrypt(iv + ct), pt)
def testCBC_Rijndael_256(self):
""" Rijndael CBC 256 """
key = '2b7e151628aed2a6abf7158809cf4f3c'
iv = '000102030405060708090a0b0c0d0e0f000102030405060708090a0b0c0d0e0f'
pt = """6bc1bee22e409f96e93d7e117393172aae2d8a571e03ac9c9eb76fac45af8e51
30c81c46a35ce411e5fbc1191a0a52eff69f2445df4f9b17ad2b417be66c3710"""
key, iv, pt = a2b_p(key), a2b_p(iv), a2b_p(pt)
alg = CBC(Rijndael(key, blockSize=32))
ct = alg.encrypt(pt, iv=iv)
self.assertEqual(alg.decrypt(iv + ct), pt)
def testMultipassEncrypt(self):
""" Test moreData usage """
alg = CBC(Rijndael(16 * chr(0), blockSize=32))
ct1 = ''
for i in range(129):
ct1 += alg.encrypt('a', more=1)
ct1 += alg.encrypt('') # flush any remaining
ct2 = alg.encrypt(129 * 'a')
self.assertNotEqual(ct1, ct2)
pt1 = alg.decrypt(ct1)
pt2 = alg.decrypt(ct2)
self.assertEqual(pt1, pt2)
pt3 = alg.decrypt('', more=1)
for i in range(len(ct2)):
pt3 += alg.decrypt(ct2[i], more=1)
pt3 += alg.decrypt('')
class PRN_Rijndael:
""" A Psudeo Random Number Generator based on Rijndael_256k_256b
The algorithm is based on Section 13.4 of:
"AES Proposal: Rijndael", Joan Daemen, Vincent Rijmen
"""
def __init__(self, seed=defaultSeed):
self.__algorithm = Rijndael(padding=noPadding(),
keySize=32,
blockSize=32)
self.reset()
self.reseed(seed)
def reset(self):
self.__algorithm.setKey(self.__algorithm.keySize *
chr(0)) # set key to all zeros
self.__state = self.__algorithm.blockSize * chr(
0) # a single block of zeros
def reseed(self, seed):
while len(seed) > 0:
if len(seed) < self.__algorithm.blockSize:
block = seed + (self.__algorithm.blockSize -
len(seed)) * chr(0)
seed = ''
else:
block = seed[:self.__algorithm.blockSize]
seed = seed[self.__algorithm.blockSize:]
self.__algorithm.setKey(self.__algorithm.encrypt(block))
def getBytes(self, numBytes):
""" Return a psuedo random byte string of length numBytes """
bytes = ''
while len(bytes) < numBytes:
bytes = bytes + self.getSomeBytes()
return bytes[:numBytes] # truncate to the requested length
def getSomeBytes(self):
""" Psuedo random bytes are generated 16 bytes at a time.
The state is updated by applying Rijndael using the Cipher
Key. The first 128 bits of the state are output as a �pseudorandom number�.
"""
self.__state = self.__algorithm.encrypt(self.__state)
return self.__state[:16]
class PRN_Rijndael:
""" A Psudeo Random Number Generator based on Rijndael_256k_256b
The algorithm is based on Section 13.4 of:
"AES Proposal: Rijndael", Joan Daemen, Vincent Rijmen
"""
def __init__(self, seed=defaultSeed):
self.__algorithm = Rijndael(padding=noPadding(),keySize=32, blockSize=32)
self.reset()
self.reseed(seed)
def reset(self):
self.__algorithm.setKey(self.__algorithm.keySize*chr(0)) # set key to all zeros
self.__state = self.__algorithm.blockSize*chr(0) # a single block of zeros
def reseed(self,seed):
while len(seed) > 0 :
if len(seed) < self.__algorithm.blockSize:
block = seed + (self.__algorithm.blockSize-len(seed))*chr(0)
seed = ''
else:
block = seed[:self.__algorithm.blockSize]
seed = seed[self.__algorithm.blockSize:]
self.__algorithm.setKey( self.__algorithm.encrypt(block) )
def getBytes(self, numBytes):
""" Return a psuedo random byte string of length numBytes """
bytes = ''
while len(bytes)< numBytes :
bytes = bytes + self.getSomeBytes()
return bytes[:numBytes] # truncate to the requested length
def getSomeBytes(self):
""" Psuedo random bytes are generated 16 bytes at a time.
The state is updated by applying Rijndael using the Cipher
Key. The first 128 bits of the state are output as a “pseudorandom number”.
"""
self.__state = self.__algorithm.encrypt(self.__state)
return self.__state[:16]
def AES(key):
return Rijndael(key, keySize=32, blockSize=16, padding=padWithPadLen())
def __init__(self, seed=defaultSeed):
self.__algorithm = Rijndael(padding=noPadding(),keySize=32, blockSize=32)
self.reset()
self.reseed(seed)
def __init__(self, seed=defaultSeed):
self.__algorithm = Rijndael(padding=noPadding(),
keySize=32,
blockSize=32)
self.reset()
self.reseed(seed)
def AES(key):
from crypto.cipher.base import padWithPadLen
from crypto.cipher.rijndael import Rijndael
return Rijndael(key, keySize=32, blockSize=16, padding=padWithPadLen())