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* Pyupgrade to Python 3.9 * updating DIRECTORY.md Co-authored-by: github-actions <${GITHUB_ACTOR}@users.noreply.github.com>
240 lines
7.7 KiB
Python
240 lines
7.7 KiB
Python
from __future__ import annotations
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from string import ascii_letters
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def encrypt(input_string: str, key: int, alphabet: str | None = None) -> str:
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"""
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encrypt
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=======
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Encodes a given string with the caesar cipher and returns the encoded
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message
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Parameters:
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-----------
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* input_string: the plain-text that needs to be encoded
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* key: the number of letters to shift the message by
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Optional:
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* alphabet (None): the alphabet used to encode the cipher, if not
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specified, the standard english alphabet with upper and lowercase
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letters is used
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Returns:
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* A string containing the encoded cipher-text
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More on the caesar cipher
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=========================
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The caesar cipher is named after Julius Caesar who used it when sending
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secret military messages to his troops. This is a simple substitution cipher
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where very character in the plain-text is shifted by a certain number known
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as the "key" or "shift".
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Example:
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Say we have the following message:
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"Hello, captain"
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And our alphabet is made up of lower and uppercase letters:
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"abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ"
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And our shift is "2"
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We can then encode the message, one letter at a time. "H" would become "J",
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since "J" is two letters away, and so on. If the shift is ever two large, or
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our letter is at the end of the alphabet, we just start at the beginning
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("Z" would shift to "a" then "b" and so on).
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Our final message would be "Jgnnq, ecrvckp"
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Further reading
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===============
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* https://en.m.wikipedia.org/wiki/Caesar_cipher
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Doctests
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========
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>>> encrypt('The quick brown fox jumps over the lazy dog', 8)
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'bpm yCqks jzwEv nwF rCuxA wDmz Bpm tiHG lwo'
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>>> encrypt('A very large key', 8000)
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's nWjq dSjYW cWq'
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>>> encrypt('a lowercase alphabet', 5, 'abcdefghijklmnopqrstuvwxyz')
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'f qtbjwhfxj fqumfgjy'
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"""
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# Set default alphabet to lower and upper case english chars
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alpha = alphabet or ascii_letters
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# The final result string
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result = ""
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for character in input_string:
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if character not in alpha:
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# Append without encryption if character is not in the alphabet
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result += character
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else:
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# Get the index of the new key and make sure it isn't too large
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new_key = (alpha.index(character) + key) % len(alpha)
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# Append the encoded character to the alphabet
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result += alpha[new_key]
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return result
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def decrypt(input_string: str, key: int, alphabet: str | None = None) -> str:
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"""
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decrypt
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=======
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Decodes a given string of cipher-text and returns the decoded plain-text
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Parameters:
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-----------
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* input_string: the cipher-text that needs to be decoded
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* key: the number of letters to shift the message backwards by to decode
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Optional:
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* alphabet (None): the alphabet used to decode the cipher, if not
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specified, the standard english alphabet with upper and lowercase
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letters is used
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Returns:
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* A string containing the decoded plain-text
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More on the caesar cipher
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=========================
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The caesar cipher is named after Julius Caesar who used it when sending
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secret military messages to his troops. This is a simple substitution cipher
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where very character in the plain-text is shifted by a certain number known
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as the "key" or "shift". Please keep in mind, here we will be focused on
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decryption.
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Example:
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Say we have the following cipher-text:
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"Jgnnq, ecrvckp"
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And our alphabet is made up of lower and uppercase letters:
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"abcdefghijklmnopqrstuvwxyzABCDEFGHIJKLMNOPQRSTUVWXYZ"
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And our shift is "2"
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To decode the message, we would do the same thing as encoding, but in
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reverse. The first letter, "J" would become "H" (remember: we are decoding)
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because "H" is two letters in reverse (to the left) of "J". We would
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continue doing this. A letter like "a" would shift back to the end of
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the alphabet, and would become "Z" or "Y" and so on.
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Our final message would be "Hello, captain"
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Further reading
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===============
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* https://en.m.wikipedia.org/wiki/Caesar_cipher
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Doctests
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========
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>>> decrypt('bpm yCqks jzwEv nwF rCuxA wDmz Bpm tiHG lwo', 8)
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'The quick brown fox jumps over the lazy dog'
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>>> decrypt('s nWjq dSjYW cWq', 8000)
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'A very large key'
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>>> decrypt('f qtbjwhfxj fqumfgjy', 5, 'abcdefghijklmnopqrstuvwxyz')
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'a lowercase alphabet'
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"""
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# Turn on decode mode by making the key negative
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key *= -1
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return encrypt(input_string, key, alphabet)
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def brute_force(input_string: str, alphabet: str | None = None) -> dict[int, str]:
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"""
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brute_force
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===========
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Returns all the possible combinations of keys and the decoded strings in the
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form of a dictionary
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Parameters:
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-----------
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* input_string: the cipher-text that needs to be used during brute-force
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Optional:
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* alphabet: (None): the alphabet used to decode the cipher, if not
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specified, the standard english alphabet with upper and lowercase
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letters is used
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More about brute force
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======================
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Brute force is when a person intercepts a message or password, not knowing
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the key and tries every single combination. This is easy with the caesar
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cipher since there are only all the letters in the alphabet. The more
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complex the cipher, the larger amount of time it will take to do brute force
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Ex:
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Say we have a 5 letter alphabet (abcde), for simplicity and we intercepted the
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following message:
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"dbc"
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we could then just write out every combination:
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ecd... and so on, until we reach a combination that makes sense:
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"cab"
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Further reading
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===============
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* https://en.wikipedia.org/wiki/Brute_force
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Doctests
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========
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>>> brute_force("jFyuMy xIH'N vLONy zILwy Gy!")[20]
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"Please don't brute force me!"
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>>> brute_force(1)
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Traceback (most recent call last):
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TypeError: 'int' object is not iterable
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"""
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# Set default alphabet to lower and upper case english chars
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alpha = alphabet or ascii_letters
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# To store data on all the combinations
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brute_force_data = {}
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# Cycle through each combination
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for key in range(1, len(alpha) + 1):
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# Decrypt the message and store the result in the data
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brute_force_data[key] = decrypt(input_string, key, alpha)
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return brute_force_data
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if __name__ == "__main__":
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while True:
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print(f'\n{"-" * 10}\n Menu\n{"-" * 10}')
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print(*["1.Encrypt", "2.Decrypt", "3.BruteForce", "4.Quit"], sep="\n")
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# get user input
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choice = input("\nWhat would you like to do?: ").strip() or "4"
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# run functions based on what the user chose
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if choice not in ("1", "2", "3", "4"):
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print("Invalid choice, please enter a valid choice")
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elif choice == "1":
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input_string = input("Please enter the string to be encrypted: ")
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key = int(input("Please enter off-set: ").strip())
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print(encrypt(input_string, key))
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elif choice == "2":
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input_string = input("Please enter the string to be decrypted: ")
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key = int(input("Please enter off-set: ").strip())
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print(decrypt(input_string, key))
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elif choice == "3":
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input_string = input("Please enter the string to be decrypted: ")
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brute_force_data = brute_force(input_string)
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for key, value in brute_force_data.items():
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print(f"Key: {key} | Message: {value}")
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elif choice == "4":
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print("Goodbye.")
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break
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