mirror of
https://github.com/markqvist/Reticulum.git
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272 lines
8.7 KiB
Python
272 lines
8.7 KiB
Python
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# MIT License
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# Copyright (c) 2021 Or Gur Arie
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# Permission is hereby granted, free of charge, to any person obtaining a copy
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# of this software and associated documentation files (the "Software"), to deal
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# in the Software without restriction, including without limitation the rights
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# to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
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# copies of the Software, and to permit persons to whom the Software is
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# furnished to do so, subject to the following conditions:
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# The above copyright notice and this permission notice shall be included in all
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# copies or substantial portions of the Software.
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# THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
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# IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
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# FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
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# AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
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# LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
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# OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
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# SOFTWARE.
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from .utils import *
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class AES:
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# AES-128 block size
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block_size = 16
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# AES-128 encrypts messages with 10 rounds
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_rounds = 10
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# initiate the AES objecy
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def __init__(self, key):
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"""
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Initializes the object with a given key.
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"""
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# make sure key length is right
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assert len(key) == AES.block_size
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# ExpandKey
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self._round_keys = self._expand_key(key)
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# will perform the AES ExpandKey phase
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def _expand_key(self, master_key):
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"""
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Expands and returns a list of key matrices for the given master_key.
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"""
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# Initialize round keys with raw key material.
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key_columns = bytes2matrix(master_key)
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iteration_size = len(master_key) // 4
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# Each iteration has exactly as many columns as the key material.
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i = 1
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while len(key_columns) < (self._rounds + 1) * 4:
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# Copy previous word.
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word = list(key_columns[-1])
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# Perform schedule_core once every "row".
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if len(key_columns) % iteration_size == 0:
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# Circular shift.
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word.append(word.pop(0))
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# Map to S-BOX.
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word = [s_box[b] for b in word]
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# XOR with first byte of R-CON, since the others bytes of R-CON are 0.
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word[0] ^= r_con[i]
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i += 1
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elif len(master_key) == 32 and len(key_columns) % iteration_size == 4:
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# Run word through S-box in the fourth iteration when using a
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# 256-bit key.
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word = [s_box[b] for b in word]
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# XOR with equivalent word from previous iteration.
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word = bytes(i^j for i, j in zip(word, key_columns[-iteration_size]))
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key_columns.append(word)
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# Group key words in 4x4 byte matrices.
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return [key_columns[4*i : 4*(i+1)] for i in range(len(key_columns) // 4)]
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# encrypt a single block of data with AES
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def _encrypt_block(self, plaintext):
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"""
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Encrypts a single block of 16 byte long plaintext.
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"""
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# length of a single block
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assert len(plaintext) == AES.block_size
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# perform on a matrix
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state = bytes2matrix(plaintext)
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# AddRoundKey
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add_round_key(state, self._round_keys[0])
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# 9 main rounds
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for i in range(1, self._rounds):
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# SubBytes
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sub_bytes(state)
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# ShiftRows
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shift_rows(state)
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# MixCols
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mix_columns(state)
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# AddRoundKey
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add_round_key(state, self._round_keys[i])
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# last round, w/t AddRoundKey step
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sub_bytes(state)
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shift_rows(state)
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add_round_key(state, self._round_keys[-1])
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# return the encrypted matrix as bytes
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return matrix2bytes(state)
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# decrypt a single block of data with AES
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def _decrypt_block(self, ciphertext):
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"""
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Decrypts a single block of 16 byte long ciphertext.
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"""
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# length of a single block
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assert len(ciphertext) == AES.block_size
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# perform on a matrix
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state = bytes2matrix(ciphertext)
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# in reverse order, last round is first
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add_round_key(state, self._round_keys[-1])
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inv_shift_rows(state)
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inv_sub_bytes(state)
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for i in range(self._rounds - 1, 0, -1):
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# nain rounds
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add_round_key(state, self._round_keys[i])
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inv_mix_columns(state)
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inv_shift_rows(state)
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inv_sub_bytes(state)
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# initial AddRoundKey phase
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add_round_key(state, self._round_keys[0])
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# return bytes
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return matrix2bytes(state)
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# will encrypt the entire data
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def encrypt(self, plaintext, iv):
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"""
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Encrypts `plaintext` using CBC mode and PKCS#7 padding, with the given
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initialization vector (iv).
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"""
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# iv length must be same as block size
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assert len(iv) == AES.block_size
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assert len(plaintext) % AES.block_size == 0
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ciphertext_blocks = []
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previous = iv
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for plaintext_block in split_blocks(plaintext):
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# in CBC mode every block is XOR'd with the previous block
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xorred = xor_bytes(plaintext_block, previous)
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# encrypt current block
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block = self._encrypt_block(xorred)
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previous = block
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# append to ciphertext
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ciphertext_blocks.append(block)
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# return as bytes
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return b''.join(ciphertext_blocks)
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# will decrypt the entire data
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def decrypt(self, ciphertext, iv):
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"""
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Decrypts `ciphertext` using CBC mode and PKCS#7 padding, with the given
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initialization vector (iv).
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"""
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# iv length must be same as block size
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assert len(iv) == AES.block_size
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plaintext_blocks = []
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previous = iv
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for ciphertext_block in split_blocks(ciphertext):
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# in CBC mode every block is XOR'd with the previous block
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xorred = xor_bytes(previous, self._decrypt_block(ciphertext_block))
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# append plaintext
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plaintext_blocks.append(xorred)
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previous = ciphertext_block
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return b''.join(plaintext_blocks)
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def test():
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# modules and classes requiered for test only
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import os
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class bcolors:
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OK = '\033[92m' #GREEN
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WARNING = '\033[93m' #YELLOW
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FAIL = '\033[91m' #RED
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RESET = '\033[0m' #RESET COLOR
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# will test AES class by performing an encryption / decryption
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print("AES Tests")
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print("=========")
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# generate a secret key and print details
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key = os.urandom(AES.block_size)
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_aes = AES(key)
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print(f"Algorithm: AES-CBC-{AES.block_size*8}")
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print(f"Secret Key: {key.hex()}")
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print()
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# test single block encryption / decryption
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iv = os.urandom(AES.block_size)
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single_block_text = b"SingleBlock Text"
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print("Single Block Tests")
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print("------------------")
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print(f"iv: {iv.hex()}")
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print(f"plain text: '{single_block_text.decode()}'")
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ciphertext_block = _aes._encrypt_block(single_block_text)
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plaintext_block = _aes._decrypt_block(ciphertext_block)
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print(f"Ciphertext Hex: {ciphertext_block.hex()}")
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print(f"Plaintext: {plaintext_block.decode()}")
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assert plaintext_block == single_block_text
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print(bcolors.OK + "Single Block Test Passed Successfully" + bcolors.RESET)
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print()
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# test a less than a block length phrase
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iv = os.urandom(AES.block_size)
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short_text = b"Just Text"
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print("Short Text Tests")
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print("----------------")
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print(f"iv: {iv.hex()}")
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print(f"plain text: '{short_text.decode()}'")
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ciphertext_short = _aes.encrypt(short_text, iv)
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plaintext_short = _aes.decrypt(ciphertext_short, iv)
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print(f"Ciphertext Hex: {ciphertext_short.hex()}")
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print(f"Plaintext: {plaintext_short.decode()}")
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assert short_text == plaintext_short
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print(bcolors.OK + "Short Text Test Passed Successfully" + bcolors.RESET)
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print()
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# test an arbitrary length phrase
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iv = os.urandom(AES.block_size)
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text = b"This Text is longer than one block"
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print("Arbitrary Length Tests")
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print("----------------------")
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print(f"iv: {iv.hex()}")
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print(f"plain text: '{text.decode()}'")
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ciphertext = _aes.encrypt(text, iv)
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plaintext = _aes.decrypt(ciphertext, iv)
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print(f"Ciphertext Hex: {ciphertext.hex()}")
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print(f"Plaintext: {plaintext.decode()}")
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assert text == plaintext
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print(bcolors.OK + "Arbitrary Length Text Test Passed Successfully" + bcolors.RESET)
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print()
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if __name__ == "__main__":
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# test AES class
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test()
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