aiootp - an asynchronous pseudo-one-time-pad based crypto and anonymity library.
Project description
aiootp - Asynchronous pseudo-one-time-pad based crypto and anonymity library.
aiootp is an asynchronous library providing access to cryptographic primatives and abstractions, transparently encrypted / decrypted file I/O and databases, as well as powerful, pythonic utilities that simplify data processing & cryptographic procedures in python code. This library’s online MRAE / AEAD cipher, called Chunky2048, is an implementation of the pseudo-one-time-pad. The aim is to create a simple, standard, efficient implementation that’s indistinguishable from the unbreakable one-time-pad cipher; to give users and applications access to user-friendly cryptographic tools; and, to increase the overall security, privacy, and anonymity on the web, and in the digital world. Users will find aiootp to be easy to write, easy to read, and fun.
Important Disclaimer
aiootp is experimental software that works with Python 3.6+. It’s a work in progress. The programming API could change with future updates, and it isn’t bug free. aiootp provides powerful security tools and misc utilities that’re designed to be developer-friendly and privacy preserving. As a security tool, aiootp needs to be tested and reviewed extensively by the programming and cryptography communities to ensure its implementations are sound. We provide no guarantees. This software hasn’t yet been audited by third-party security professionals.
Quick install
pip3 install --user --upgrade aiootp
Some Examples
Users can create and modify transparently encrypted databases:
#
import aiootp
# Make a new user key for encryption / decryption with a fast,
# cryptographically secure pseudo-random number generator ->
key = await aiootp.acsprng()
# Create a database object with it ->
db = await aiootp.AsyncDatabase(key)
# Users can also use passwords to open a database, if necessary.
# Although passwords & passphrases are low-entropy, & not recommended,
# here's how to use them more safely ->
tokens = await aiootp.AsyncDatabase.agenerate_profile_tokens(
"server_url", # An unlimited number of arguments can be passed
"email_address", # here as additional, optional credentials.
username="username",
password="password",
salt="optional salt keyword argument",
)
db = await aiootp.AsyncDatabase.agenerate_profile(tokens)
# Data within databases are organized by ``tag``s ->
async with db: # <---Context saves data to disk when closed
db["tag"] = {"data": "can be any json serializable object"}
db["bitcoin"] = "0bb6eee10d2f8f45f8a"
db["lawyer"] = {"#": "555-555-1000", "$": 13000.50}
db["safehouses"] = ["Dublin Forgery", "NY Insurrection"]
# Databases also have access to conversion functions for saving
# bytes type data ->
db["bytes data"] = await db.abase64_encode(b"fash smasher")
assert b"fash smasher" == await db.abase64_decode(db["bytes data"])
# Access to data is open to the user, so care must be taken
# not to let external api calls touch the database without
# accounting for how that can go wrong.
# Sensitive tags can be hashed into uuids of arbitrary size ->
await db.ametatag("clients")
email_uuids = await db.clients.auuids("emails", size=64)
for email_address in ["brittany@email.com", "john.doe@email.net"]:
hashed_tag = await email_uuids(email_address)
db.clients[hashed_tag] = "client account data"
db["clients salt"] = await email_uuids.aresult(exit=True)
# Data of any type can be verified using an hmac ->
hmac = await db.ahmac({"id": 1234, "payload": "message"})
await db.atest_hmac({"id": 1234, "payload": "message"}, hmac=hmac)
>>> True
# Although, datatypes where order of values is not preserved may fail to
# validate ->
await db.atest_hmac({"payload": "message", "id": 1234}, hmac=hmac)
>>> ValueError: "HMAC of the data stream isn't valid."
# Create child databases accessible from the parent by a ``metatag`` ->
metatag = "child"
molly = await db.ametatag(metatag)
molly["hobbies"] = ["skipping", "punching"]
molly["hobbies"].append("reading")
molly["hobbies"] is db.child["hobbies"]
>>> True
assert isinstance(molly, aiootp.AsyncDatabase)
# If the user no longer wants a piece of data, pop it out ->
await molly.apop("hobbies")
>>> ["skipping", "punching", "reading"]
"hobbies" in molly
>>> False
# Delete a child database from the filesystem ->
await db.adelete_metatag("child")
db.child["hobbies"]
>>> AttributeError: 'AsyncDatabase' object has no attribute 'child'
# Write database changes to disk with transparent encryption ->
await db.asave()
# Make mirrors of databases ->
new_key = await aiootp.acsprng()
new_db = await aiootp.AsyncDatabase(new_key)
await new_db.amirror_database(db)
assert new_db["lawyer"] is db["lawyer"]
# Or make namespaces out of databases for very efficient lookups ->
namespace = await new_db.ainto_namespace()
assert namespace.bitcoin == new_db["bitcoin"]
assert namespace.lawyer is new_db["lawyer"]
# Delete a database from the filesystem ->
await db.adelete_database()
# Initialization of a database object is more computationally expensive
# than entering its context manager. So keeping a reference to a
# preloaded database is a great idea, either call ``asave`` / ``save``
# periodically, or open a context with the reference whenever wanting to
# capture changes to the filesystem ->
async with new_db as db:
print("Saving to disk...")
# As databases grow in the number of tags & metatags & the size of
# the data within, it may become desireable to load data from them
# as needed, instead of all at once during initialization. This can
# be done with the ``preload`` boolean keyword argument ->
db["tag_test"] = "test value"
await db.ametatag("metatag_test")
await db.asave()
quick_db = await aiootp.AsyncDatabase(key, preload=False)
# Although, now to retrieve elements from an async database, the
# ``aquery`` method must first be used to load tags into the cache ->
quick_db["tag_test"]
>>> None
loaded_value = await quick_db.aquery("tag_test")
assert loaded_value == "test value"
assert quick_db["tag_test"] == "test value"
# Metatags need to be loaded manually as well ->
quick_db.metatag_test
>>> AttributeError:
await quick_db.ametatag("metatag_test")
assert type(quick_db.metatag_test) == aiootp.AsyncDatabase
# Transparent and automatic encryption makes persisting sensitive
# information very simple. Though, if users do want to encrypt /
# decrypt things manually, then databases allow that too ->
data_name = "saturday clients"
clients = ["Tony", "Maria"]
encrypted = await db.aencrypt(filename=data_name, plaintext=clients)
decrypted = await db.adecrypt(filename=data_name, ciphertext=encrypted)
clients == decrypted
>>> True
# All encrypted messages have timestamps that can be used to enforce
# limits on how old messages can be (in seconds) before they are
# rejected ->
decrypted = await db.adecrypt(data_name, encrypted, ttl=25)
>>> TimeoutError: Timestamp expired by <10> seconds.
#What other tools are available to users?:
#
import aiootp
# Async & synchronous versions of almost everything in the library ->
assert await aiootp.asha_512("data") == aiootp.sha_512("data")
key = aiootp.csprng()
db = aiootp.Database(key)
async_db = await aiootp.AsyncDatabase(key)
assert db._root_filename == async_db._root_filename
# Precomputed & organized values that can aid users, like:
# A dictionary of prime numbers grouped by their bit-size ->
aiootp.primes[513][0] # <- The first 65 byte prime
aiootp.primes[2048][-1] # <- The last 256 byte prime
# Elliptic curve 25519 diffie-hellman exchange protocols ->
ecdhe_key = aiootp.X25519().generate()
with ecdhe_key.dh3_client() as exchange:
response = internet.post(exchange())
exchange(response)
clients_kdf = exchange.result()
# This is how a peer can accept the exchange ->
ecdhe_key = aiootp.X25519().generate()
pkB, pkD = client_public_keys = internet.receive()
server = ecdhe_key.dh3_server(peer_identity_key=pkB, peer_ephemeral_key=pkD)
with server as exchange:
internet.post(exchange.exhaust())
servers_kdf = exchange.result()
# Success! Now both the client & server peers share an identical
# sha3_512 hashing object to create shared keys with ->
assert clients_kdf.digest() == servers_kdf.digest()
# Edwards curve 25519 signing & verification ->
# In a land, long ago ->
user_alice = Ed25519().generate()
internet.send(user_alice.public_bytes.hex())
# Alice wants to sign a document so that Bob can prove she wrote it.
# So, Alice sends the public key bytes of the key she wants to
# associate with her identity, the document & the signature ->
document = b"DesignDocument.cad"
signed_document = user_alice.sign(document)
message = {
"document": document,
"signature": signed_document,
"public_key": user_alice.public_bytes.hex(),
}
internet.send(message)
# In a land far away ->
alices_message = internet.receive()
# Bob sees the message from Alice! Bob already knows Alice's public
# key & she has reason believe it is genuinely hers. So, she'll
# import Alice's known public key to verify the signed document ->
assert alices_message["public_key"] == alices_public_key
alice_verifier = Ed25519().import_public_key(alices_public_key)
alice_verifier.verify(
alices_message["signature"], alices_message["document"]
)
internet.send(b"Beautiful work, Alice! Thanks ^u^")
# The verification didn't throw an exception! So, Bob knows the file
# was signed by Alice.
# Symmetric pseudo-one-time-pad encryption of json data ->
plaintext = {"account": 3311149, "titles": ["queen b"]}
encrypted = aiootp.json_encrypt(plaintext, key=key)
decrypted = aiootp.json_decrypt(encrypted, key=key)
assert decrypted == plaintext
# Symmetric pseudo-one-time-pad encryption of binary data ->
binary_data = b"This bytes string is also valid plaintext."
encrypted = aiootp.bytes_encrypt(binary_data, key=key)
decrypted = aiootp.bytes_decrypt(encrypted, key=key)
assert decrypted == binary_data
# The Chunky2048 class carries the key so users don't have to pass
# it around every where ->
pad = aiootp.Chunky2048(key)
encrypted = pad.bytes_encrypt(binary_data)
decrypted = pad.bytes_decrypt(encrypted)
# The class also has access to an encoder for transforming
# ciphertext to & from its default dictionary format ->
bytes_ciphertext = pad.io.json_to_bytes(encrypted)
dict_ciphertext = pad.io.bytes_to_json(bytes_ciphertext)
# As well as tools for saving ciphertext to files on disk as bytes ->
path = aiootp.DatabasePath() / "testing_ciphertext"
pad.io.write(path, encrypted)
assert encrypted == pad.io.read(path)
# Or ciphertext can be encoded to & from a urlsafe string ->
urlsafe_ciphertext = pad.io.bytes_to_urlsafe(bytes_ciphertext)
bytes_ciphertext = pad.io.urlsafe_to_bytes(urlsafe_ciphertext)
# These urlsafe tokens have their own convenience functions ->
token = pad.make_token(b"binary data")
assert b"binary data" == pad.read_token(token)
# Ratcheting Opaque Password Authenticated Key Exchange (ROPAKE) with
# online services ->
db = aiootp.Database(pad.key)
with aiootp.Ropake.client_registration(db) as registration:
server_response = internet.post("service-url.com", json=registration())
registration(server_response)
shared_keys = registration.result()
# The client is securely registered with the service if there was no
# active adversary in the middle. The user can now authenticate & login ->
with aiootp.Ropake.client(db) as authentication:
server_response = internet.post("service-url.com", authentication())
authentication(server_response)
shared_keys = authentication.result()
# Upon the first uncompromised registration or authentication, then
# future authentications will be immune to adversaries in the middle
# because the protocol generates new keys by combining the prior key,
# the current ecdhe ephemeral key, & the revealed keyed password that
# was transmitted with an extra mask during the prior exchange. The
# keyed password authenticates the user & the server to each other when
# the commit is revealed, the ephemeral ecdhe key assures future security,
# & the prior key encrypts & HMACs the authentication packets which
# provides privacy, & added authentication, & the KDF which combines all
# these keys to ensure forward security.
#Generators under-pin most procedures in the library, let’s take a look ->
#
from aiootp import Chunky2048, json
pad = Chunky2048() # <---Auto-generates an encryption key
salt = pad.generate_salt() # <---A NEW salt MUST be used every encryption!
pid = aiootp.sha_256("any additional data") # <---Must be known by the decrypting party
plaintext_bytes = json.dumps({"message": "secretsssss"}).encode()
# Yields padded plaintext in chunks of 256 bytes ->
plaintext_stream = pad.plaintext_stream(plaintext_bytes, salt=salt, pid=pid)
datastream = plaintext_stream.bytes_to_int()
# An endless stream of forward + semi-future secure hex keys ->
keystream = pad.keys(salt=salt, pid=pid)
# This is used to authenticate the ciphertext & additional data ->
hmac = pad.StreamHMAC(salt=salt, pid=pid).for_encryption()
# xor's the plaintext chunks with key chunks ->
with pad.xor(datastream, key=keystream, validator=hmac) as encrypting:
# ``list`` returns all generator results in a list
ciphertext = encrypting.list()
ciphertext_authentication = hmac.finalize()
siv = hmac.siv
# When receiving ciphertext, the user must first validate the hmac of
# the ciphertext before trusting the plaintext that's revealed ->
hmac = pad.StreamHMAC(salt=salt, pid=pid, siv=siv).for_decryption()
keystream.reset()
decipher = pad.xor(ciphertext, key=keystream, validator=hmac)
with decipher.int_to_bytes() as decrypting:
padding_key = pad.padding_key(salt=salt, pid=pid)
padded_data = decrypting.join(b"")
hmac.finalize()
hmac.test_hmac(ciphertext_authentication)
# If no ValueError was raised, the authentication has passed!
# Continue with processing the plaintext ->
decrypted = pad.io.depad_bytes(padded_data, salted_key=padding_key)
plaintext_bytes == decrypted
>>> True
# This example was a low-level look at the encryption algorithm. And it
# was only a few lines of code. The Comprende class makes working with
# generators a breeze, & working with generators makes solving problems
# in bite-sized chunks a breeze. ->
padded_plaintext = pad.plaintext_stream(plaintext_bytes, salt=salt, pid=pid).list()
assert isinstance(padded_plaintext, list)
for block in padded_plaintext:
assert len(block) == 256
# We just used the ``list`` end-point to get the full series
# of results from the underlying generator. These results are lru-cached
# to facilitate their efficient reuse for alternate computations. The
# ``Comprende`` context managers clear the opened instance's cache on exit,
# this clears every instance's cache ->
aiootp.Comprende.clear_class()
# The other end-points can be found under ``aiootp.Comprende.eager_methods`` ->
{
'adeque',
'adict',
'aexhaust', # <- Doesn't cache results, only returns the last element
'ajoin',
'alist',
'aset',
'deque',
'dict',
'exhaust', # <- Doesn't cache results, only returns the last element
'join',
'list',
'set',
}
# A lot of this magic with generators is made possible with a sweet little
# ``comprehension`` decorator. It reimagines the generator interface by
# wrapping generators in the innovative ``Comprende`` class, giving every
# generator access to a plethora of data processing & cryptographic utilities
# right out of the box ->
@aiootp.comprehension()
def gen(x=None, y=None):
z = yield x + y
return x * y * z
# Drive the generator forward with a context manager ->
with gen(x=1, y=2) as example:
z = 3
# Calling the object will send ``None`` into the coroutine by default ->
sum_of_x_y = example()
assert sum_of_x_y == 3
# Passing ``z`` will send it into the coroutine, cause it to reach the
# return statement & exit the context manager ->
example(z)
# The result returned from the generator is now available ->
product_of_x_y_z = example.result()
assert product_of_x_y_z == 6
# The ``example`` variable is actually the ``Comprende`` object,
# which redirects values to the wrapped generator's ``send()``
# method using the instance's ``__call__()`` method.
# Here's another example ->
@aiootp.comprehension()
def one_byte_numbers():
for number in range(256):
yield number
# Chained ``Comprende`` generators are excellent inline data processors ->
base64_data = [
b64_byte
for b64_byte
in one_byte_numbers().int_to_bytes(1).to_base64()
]
# This converted each number to bytes then base64 encoded them.
# We can wrap other iterables to add functionality to them ->
@aiootp.comprehension()
def unpack(iterable):
for item in iterable:
yield item
# This example just hashes each output then yields them
for hex_hash in unpack(base64_data).sha_256():
print(hex_hash)
# Async ``Comprende`` coroutines have almost exactly the same interface as
# synchronous ones ->
@aiootp.comprehension()
async def gen(x=None, y=None):
# Because having a return statement in an async generator is a
# SyntaxError, the return value is expected to be passed into
# UserWarning, and then raised to propagate upstream. It's then
# available from the instance's ``aresult`` method ->
z = yield x + y
result = x * y * z
raise UserWarning(result)
# Drive the generator forward.
async with gen(x=1, y=2) as example:
z = 3
# Awaiting the ``__call__`` method will send ``None`` into the
# coroutine by default ->
sum_of_x_y = await example()
assert sum_of_x_y == 3
# Passing ``z`` will send it into the coroutine, cause it to reach the
# raise statement which will exit the context manager gracefully ->
await example(z)
# The result returned from the generator is now available ->
product_of_x_y_z = await example.aresult()
assert product_of_x_y_z == 6
# Let's see some other ways async generators mirror synchronous ones ->
@aiootp.comprehension()
async def one_byte_numbers():
for number in range(256):
yield number
# This is asynchronous data processing ->
base64_data = [
b64_byte
async for b64_byte
in one_byte_numbers().aint_to_bytes(1).ato_base64()
]
# This converted each number to bytes then base64 encoded them.
# We can wrap other iterables to add asynchronous functionality to them ->
@aiootp.comprehension()
async def unpack(iterable):
for item in iterable:
yield item
# Want only the first twenty results? ->
async for hex_hash in unpack(base64_data).asha_256()[:20]:
# Then you can slice the generator.
print(hex_hash)
# Users can slice generators to receive more complex output rules, like:
# Getting every second result starting from the third result to the 50th ->
async for result in unpack(base64_data)[3:50:2]:
print(result)
# Although, negative slice numbers are not supported.
# ``Comprende`` generators have loads of tooling for users to explore.
# Play around with it and take a look at the other chainable generator
# methods in ``aiootp.Comprende.lazy_generators``.
{
"_agetitem",
"_getitem",
"aascii_to_int",
"abin",
"abytes",
"abytes_decrypt",
"abytes_encrypt",
"abytes_to_hex",
"abytes_to_int",
"adebugger",
"adecode",
"adecrypt",
"adelimit",
"adelimited_resize",
"adepad_plaintext",
"aencode",
"aencrypt",
"afeed",
"afeed_self",
"afrom_base",
"afrom_base64",
"ahalt",
"ahex",
"ahex_to_bytes",
"aindex",
"aint",
"aint_to_ascii",
"aint_to_bytes",
"ajson_dumps",
"ajson_loads",
"amap_decipher",
"amap_encipher",
"apad_plaintext",
"apasscrypt",
"arandom_sleep",
"areplace",
"aresize",
"ascii_to_int",
"asha_256",
"asha_256_hmac",
"asha_512",
"asha_512_hmac",
"aslice",
"asplit",
"astr",
"asum_passcrypt",
"asum_sha_256",
"asum_sha_512",
"atag",
"atimeout",
"ato_base",
"ato_base64",
"axor",
"azfill",
"bin",
"bytes",
"bytes_decrypt",
"bytes_encrypt",
"bytes_to_hex",
"bytes_to_int",
"debugger",
"decode",
"decrypt",
"delimit",
"delimited_resize",
"depad_plaintext",
"encode",
"encrypt",
"feed",
"feed_self",
"from_base",
"from_base64",
"halt",
"hex",
"hex_to_bytes",
"index",
"int",
"int_to_ascii",
"int_to_bytes",
"json_dumps",
"json_loads",
"map_decipher",
"map_encipher",
"pad_plaintext",
"passcrypt",
"random_sleep",
"replace",
"resize",
"sha_256",
"sha_256_hmac",
"sha_512",
"sha_512_hmac",
"slice",
"split",
"str",
"sum_passcrypt",
"sum_sha_256",
"sum_sha_512",
"tag",
"timeout",
"to_base",
"to_base64",
"xor",
"zfill",
}
# Let's look at a more complicated example with the one-time pad
# keystreams. There are many uses for endless streams of deterministic
# key material outside of one-time pad cipher keys. They can, for instance,
# give hash tables order that's cryptographically determined & obscured ->
ordered_entries = {}
salt = await aiootp.asalt()
names = aiootp.akeys(key, salt=salt)
# Resize each output of ``names`` to 32 characters, tag each output with
# an incrementing number, & stop the stream after 0.01 seconds ->
async for index, name in names.aresize(32).atag().atimeout(0.01):
ordered_entries[name] = f"{index} data organized by the stream of hashes"
# Retrieving items in the correct order requires knowing both ``key`` & ``salt``
async for index, name in aiootp.akeys(key, salt=salt).aresize(32).atag():
try:
assert ordered_entries[name] == f"{index} data organized by the stream of hashes"
except KeyError:
print(f"There are no more entries after {index} iterations.")
assert index == len(ordered_entries) + 1
break
# There's a prepackaged ``Comprende`` generator function that does
# encryption / decryption of key ordered hash maps. It needs bytes
# data to work on though. First let's make an actual encryption key
# stream that's different from ``names`` ->
pid = aiootp.sha_256(key, salt, "any additional data")
key_stream = aiootp.akeys(key, salt=salt, pid=pid)
# And example plaintext ->
plaintext = 100 * b"Some kinda message..."
# We'll have to safely pad the plaintext to a multiple of 256 bytes ->
padding_key = aiootp.padding_key(key, salt=salt, pid=pid)
padded_data = aiootp.pad_plaintext(plaintext, salted_key=padding_key)
# We can now stream the data & ciphertext authentication process ->
data_stream = aiootp.adata(padded_data)
hmac = aiootp.StreamHMAC(key, salt=salt, pid=pid).for_encryption()
# And let's make sure to clean up after ourselves with a context manager ->
async with data_stream.amap_encipher(names, key_stream, validator=hmac) as encrypting:
# ``adata`` takes a sequence, & ``amap_encipher`` takes two iterables,
# a stream of names for the hash map, & the stream of key material.
ciphertext_hashmap = await encrypting.adict()
ciphertext_authentication = await hmac.afinalize()
siv = hmac.siv
# Now we'll pick the chunks out in the order produced by ``names`` to
# decrypt them ->
ciphertext_stream = aiootp.apick(names, ciphertext_hashmap)
# The decrypting party will likely have to instantiate their own
# keystream object, but we'll just reset ours for convenience ->
await key_stream.areset()
# Next we'll authenticate & decrypt the ciphertext hashmap in the
# correct order ->
hmac = aiootp.StreamHMAC(key, salt=salt, pid=pid, siv=siv).for_decryption()
async with ciphertext_stream.amap_decipher(key_stream, validator=hmac) as decrypting:
decrypted = await decrypting.ajoin(b"")
await hmac.afinalize()
await hmac.atest_hmac(ciphertext_authentication)
# We can now remove any padding from the data to reveal the plaintext ->
assert plaintext == aiootp.depad_plaintext(decrypted, salted_key=padding_key)
# This is neat, & makes sharding & authenticating encrypted data
# incredibly easy.
#Let’s take a deep dive into the low-level xor procedure used to implement the pseudo-one-time-pad:
#
import aiootp
# It is a ``Comprende`` generator ->
@aiootp.comprehension()
# ``data`` is an iterable of 256 byte integers that are either plaintext
# or ciphertext. ``key`` should be an instance of the ``keys`` generator.
# And, ``validator`` should be an instance of the ``StreamHMAC`` class. ->
def xor(data, *, key, validator):
# Return the necessary method & coroutine pointers ->
datastream, keystream, validated_xor, hmac_hexdigest = (
xor_shortcuts(data, key, validator)
)
# We use the first block of plaintext (which is prepended with an
# 8-byte timestamp & a 16-byte random, ephemeral & automatically
# generated SIV-key) to derive a syntheic IV, & use it to seed the
# keystream & validator with globally unique entropy ->
yield SyntheticIV.validated_xor(datastream, keystream, validator)
for chunk in datastream:
# We use the output of the validator's current state to
# continuously seed the keystream with message dependent entropy ->
seed = hmac_hexdigest()
# We contantenate two 128 byte key chunks together ->
key_chunk = int(keystream(seed) + keystream(seed), 16)
# Then xor the 256 byte key chunk with the 256 byte data chunk
# and use the validator to update the HMAC with the ciphertext ->
result = validator.validated_xor(chunk, key_chunk)
if result >> 2048:
# If the result is for some reason larger than 256 bytes,
# (2048-bits), we abort the procedure, & warn the user ->
raise ValueError(EXCEEDED_BLOCKSIZE)
# Then we yield the result ->
yield result
# This is a very efficient, online-AEAD, salt-reuse/misuse resistant,
# pseudo-one-time-pad cipher algorithm. It's built on generators,
# which makes it simple to grok & compose with additional funcitonality.
# It's backed by an infinite stream of non-repeating key material,
# efficiently produced from a finite-sized key, an ephemeral salt,
# context & content data, & the sha3_512 algorithm.
#Here’s a quick overview of this package’s modules:
#
import aiootp
# Commonly used constants, datasets & functionality across all modules ->
aiootp.commons
# The basic utilities & abstractions of the package's architecture ->
aiootp.generics
# This module is responsible for providing entropy to the package ->
aiootp.randoms
# The higher-level abstractions used to implement the pseudo-one-time pad ->
aiootp.ciphers
# The higher-level abstractions used to create / manage key material ->
aiootp.keygens
# Common system paths & the ``pathlib.Path`` utility ->
aiootp.paths
# Global async functionalities & abstractions ->
aiootp.asynchs
# Decorators & classes able to benchmark async/sync functions & generators ->
aiootp.debuggers
#FAQ
Q: What is the one-time-pad?
A: It’s a provably unbreakable cipher. It’s typically thought to be too cumbersome a cipher because it has strict requirements. Key size is one requirement, since keys must be at least as large as the plaintext in order to ensure this unbreakability. We’ve simplified this requirement in an attempt to create a pseudo-one-time-pad that’s indistinguishable from a one-time-pad using a forward secret and semi-future secret key ratchet algorithm, with ephemeral salts for each stream, allowing users to securely produce endless streams of key material as needed from a single finite size 512-bit long-term key. This algorithmic approach lends itself to great optimizations, since hash processing hardware/sorftware is continually pushed to the edges of efficiency.
Q: Isn’t this technically a stream cipher?
- A: For sure, one-time pads are stream ciphers. Though, if we trust that pseudo-random functions (PRFs) exist, then by definition, their outputs are indistinguishable from truly random bits. Because of this, it’s proven that pseudo-one-time-pads are computationally secure if they use secure PRFs. We conjecture that the sha3 hash functions are either PRFs, or are close with negligible difference. In our view, they’re ideal candidates for the role of mimicking PRFs because:
they utilize large >512-bit internal hidden states
their cryptographic permutations are of high quality
they’re irreversible & non-simulatable without knowing thier internal states
loss of information occurs as they process data & produce digests
they’re standardized cryptographic hash functions designed with wide security margins
True random purists should note that even something as complicated, & seemingly unpredictable, as quantum mechanical events, can in theory be the result of rather simple & predictable processes. We in no way claim to be quantum physicists. It, however, seems fitting in a discussion on the existence of randomness, & when challenging the conventional notion that the natural world is quintessential randomness, when none of that is proven (or provable) mathematically. This problem is related to several impossibility proofs [1][2][3].
Q: What do you mean the ``aiootp.keys`` generator produces forward & semi-future secure key material?
A: The infinite stream of key material produced by that generator has amazing properties. Under the hood it’s a hashlib.sha3_512 key ratchet algorithm. It’s internal state consists of a seed hash, & three hashlib.sha3_512 objects primed iteratively with the one prior and the seed hash’s seed. The first object is updated with the seed hash, its prior output, and the entropy that may be sent into the generator as a coroutine. This first object’s digest is then used to update the last two objects before yielding the last two’s concatenated results. The seed to the seed hash is itself the hash of the input key material, a random salt, and a user-defined ID value which can safely differentiate streams with the same key material. This algorithm is forward secure because compromising a future key will not compromise past keys since these hashes are irreversibly constructed. It’s also semi-future secure since having a past key doesn’t allow you to compute future keys without also compromising the seed hash, and the first ratcheting hashlib object. Since those two states are never disclosed or used for encryption, the key material produced is future secure with respect to itself only. Full future-security would allow for the same property even if the seed & ratchet object’s states were compromised. This feature can, however, be added to the algorithm since the generator itself can receive entropy externally from a user at any arbitrary point in its execution, say, after computing a shared diffie-hellman exchange key.
Q: How fast is this implementation of the one-time pad cipher?
A: Well, because it relies on hashlib.sha3_512 hashing to build key material streams, it’s rather efficient, encrypting & decrypting about 20 MB/s on a ~1.5 GHz core. This is slower than most other stream ciphers, and without optimizations. However, using sha3_512 ASICs could make this algorithm competitively fast.
Q: Why make a new cipher when AES is strong enough?
A: Although primatives like AES are strong enough for now, there’s no guarantee that future hardware or algorithms won’t be developed that break them. In fact, AES’s theoretical bit-strength has dropped over the years because of hardware and algorithmic developments. It’s still considered a secure cipher, but the one-time pad isn’t considered theoretically “strong enough”, instead it’s mathematically proven to be unbreakable. Such a cryptographic guarantee is too profound not to develop further into an efficient, accessible standard.
Q: What size keys does this one-time pad cipher use?
A: It’s been designed to work with 512-bit hexidecimal keys.
Q: What’s up with the ``AsyncDatabase`` / ``Database``?
A: The idea is to create an intuitive, pythonic interface to a transparently encrypted and decrypted persistence tool that also cryptographically obscures metadata. It’s designed to work with json serializable data, which gives it native support for some basic python datatypes. It needs improvement with regard to disk memory efficiency. So, it’s still a work in progress, albeit a very nifty one.
Q: Why are the modules transformed into ``Namespace`` objects?
A: We overwrite our modules in this package to have a more fine-grained control over what part of the package’s internal state is exposed to users and applications. The goal is make it more difficult for users to inadvertently jeopardize their security tools, and minimize the attack surface available to adversaries. The aiootp.Namespace class also makes it easier to coordinate and decide the library’s UI/UX across the package.
Known Issues
The test suite for this software is under construction, & what tests have been published are currently inadequate to the needs of cryptography software.
None of the hash functions in the public facing part of the library are to spec. This is because all inputs to the hash functions from the generics.py module are put into a tuple & stringified before hashing for user-friendliness, speed, readibility & the power of being to hash any python object that has a repr. This behaviour is purposeful, but can still be an issue.
This package is currently in beta testing & active development. Contributions are welcome. Send us a message if you spot a bug or security vulnerability:
< 31FD CC4F 9961 AFAC 522A 9D41 AE2B 47FA 1EF4 4F0A >
Changelog
Changes for version 0.19.0
Major Changes
Security Upgrade: The package’s cipher was changed to an online, authenticated scheme with salt reuse / misuse resistance. This was acheived through a few backwards incompatible techniques:
A synthetic IV (SIV) is calculated from the keyed-hash of the first 256-byte block of plaintext. The SIV is then used to seed the keystream generator, & is used to update the validator object. This ensures that if the first block is unique, then the whole ciphertext will be unique.
A 16-byte ephemeral & random SIV-key is also prepended to the first block of plaintext during message padding. Since this value is also hashed to derive the SIV, this key gives a strong guarantee that a given message will produce a globally unique ciphertext.
An 8-byte timestamp is prepended to the first block of plaintext during padding. Timestamps are inherently sequential, they can be verified by a user within some bounds, & can also be used to mitigate replay attacks. Since it’s hashed to make the SIV, then it helps make the entire ciphertext unique.
After being updated with each block of ciphertext, the validator’s current state is again fed into the keystream generator as a new rotating seed. This mitigation is limited to ensuring only that every following block of ciphertext to a block which is unique will also be unique. More specifically this means that: if all other mitigations fail to be unique, or are missing, then the first block which is unique will appear the same, except for the bits which have changed, but, all following blocks will be randomized. This limitation could be avoided with a linear expansion in the ciphertext size by generating an SIV for each block of plaintext. This linear expansion is prohibitive as a default setting, but the block level secrecy, even when all other mitigations fail, is enticing. This option may be added in the future as a type of padding mode on the plaintext.
The SIV-key is by far the most important mitigation, as it isn’t feasibly forgeable by an adversary, & therefore also protects against attacks using encryption oracles. These changes can be found in the SyntheticIV class, the (en/de)cipher & xor generators, & the StreamHMAC class in the ciphers.py module. The padding changes can also be found in the new Padding class in the generics.py module. The SIV is attached in the clear with ciphertexts & was designed to function with minimal user interaction. It needs only to be passed into the StreamHMAC class during decryption – during encryption it’s automatically generated & stored in the StreamHMAC validator object’s siv property attribute.
Security Patch: The internal sha3_512 kdf’s to the akeys, keys, abytes_keys & bytes_keys keystream generators are now updated with 72 bytes of (64 key material + 8 padding), instead of just 64 bytes of key material. 72 bytes is the bitrate of the sha3_512 object. This change causes the internal state of the object to be permuted for each iteration update & before releasing a chunk of key material. Frequency analysis of ciphertext bytes didn’t smooth out to the cumulative distribution expected for all large ciphertexts prior to this change. But after the change the distribution does normalize as expected. This indicates that the key material streams were biased away from random in a small but measurable way. Although, no particular byte values seem to have been preferred by this bias, this is a huge shortcoming with unknown potential impact on the strength of the package’s cipher. This update is strongly recommended & is backwards incompatible.
This update gives a name to the package’s pseudo-one-time-pad cipher implementation. It’s now called Chunky2048! The OneTimePad class’ name was updated to Chunky2048 to match the change.
The PreemptiveHMACValidation class & its related logic in the StreamHMAC class was removed. The chaining of validator output into the keystream makes running the validator over the ciphertext separately or prior to the decryption process very costly. It would either mean recalculating the full hash of the ciphertext a second time to reproduce the correct outputs during each block, or a large linear memory increase to hold all of its digests to be fed in some time after preemtive validation. It’s much simpler to remove that functionality & potentially replace it with something else that fits the user’s applications better. For instance, the current_digest & acurrent_digest methods can produce secure, 32-byte authentication tags at any arbitrary blocks throughout the cipher’s runtime, which validate the cipehrtext up to that point. Or, the next_block_id & anext_block_id methods, which are a more robust option because each id they produce validates the next ciphertext block before updating the internal state of the validator. This acts as an automatic message ordering algorithm, & leaves the deciphering party’s state unharmed by dropped packets or manipulated ciphertext.
The update_key & aupdate_key methods were also added to the StreamHMAC class. They allow the user to update the validators’ internal key with new entropy or context information during its runtime.
The Comprende class now takes a chained keyword-only argument which flags an instance as a chained generator. This flag allows instances to communicate up & down their generator chain using the shared Namespace object accessible by their messages attribute.
The chainable Comprende generator functions had their internals altered to allow them to receive, & pass down their chain, values sent from a user using the standard coroutine send & asend method syntax.
Comprende instances no longer automatically reset themselves every time they enter their context managers or when they are iterated over. This makes their interface more closely immitate the behavior of async/sync generator objects. To get them to reset, the areset or reset methods must be used. The message chaining introduced in this update allows chains of Comprende async/sync generators to inform each other when the user instructs one of them to reset.
The standard library’s hmac module is now used internally to the generics.py module’s sha_512_hmac, sha_256_hmac, asha_512_hmac & asha_256_hmac functions. They still allow any type of data to be hashed, but also now default to hashing bytes type objects as they are given.
The new Domains class, found in generics.py, is now used to encode constants into deterministic pseudo-random 8-byte values for helping turn hash function outputs into domain-specific hashes. Its use was included throughout the library. This method has an added benefit with respect to this package’s usage of SHA-3. That being, the bitrate for both sha3_512 & sha3_256 are (2 * 32 * k) + 8 bytes, where k = 1 for sha3_512 & k = 2 for sha3_256. This means that prepending an 8-byte domain string to their inputs also makes it more efficient to add some multiple of key material to make the input data precisely equal the bitrate. More info on domain-specific hashing can be found here.
A new DomainsKDF class in cipehrs.py was added to create a more standard & secure method of key derivation to the library which also incorporates domain separation. Its use was integrated thoughout the AsyncDatabase & Database classes to mitigate any further vulnerabilities of their internal key-derivation functions. The database classes now also use bytes-type keys internally, instead of hex strings.
The Passcrypt class now contains methods which create & validate passcrypt hashes which have their settings & salt attached to them. Instances can now also be created with persistent settings that are automatically sent into instance methods.
Minor Changes
Many fixes of docstrings, typos & tutorials.
Many refactorings: name changes, extracted classes / functions, reorderings & moves.
Various code clean-ups, efficiency & usability improvements.
Many constants used throughout the library were given names defined in the commons.py module.
Removed extraneous functions throughout the library.
The asymmetric key generation & exchange functions/protocols were moved from the ciphers.py module to keygens.py.
Add missing modules to the MANIFEST.rst file.
Added a UniformPrimes class to the __datasets module for efficient access to primes that aren’t either mostly 1 or 0 bits, as is the case for the primes helper table. These primes are now used in the Hasher class’ amask_byte_order & mask_byte_order methods.
The time_safe_equality & atime_safe_equality methods are now standalone functions available from the generics.py module.
Added reset_pool to the Processes & Threads classes. Also fixed a missing piece of logic in their submit method.
Added various conversion values & timing functions to the asynchs.py module.
The make_uuid & amake_uuid coroutines had their names changed to make_uuids & amake_uuids.
Created a new Datastream class in generics.py to handle buffering & resizing iterable streams of data. It enables simplifying logic that must happen some number of iterations before the end of a stream. It’s utilized in the Padding class’ generator functions available as chainable Comprende methods.
The data & adata generators can now produce a precise number of size-length blocks as specified by a user. This gets rid of the confusing usage of the old stop keyword-only argument, which stopped a stream after approximately size number of elements.
Improved the efficiency & safety of entropy production in the randoms.py module.
Changes for version 0.18.1
Major Changes
Security Patch: Deprecated & replaced an internal kdf for saving database tags due to a vulnerability. If an adversary can get a user to reveal the value returned by the hmac method when fed the tag file’s filename & the salt used for that encrypted tag, then they could deduce the decryption key for the tag. A version check was added only for backwards compatibility & will be removed on the next update. All databases should continue functioning as normal, though all users are advised to re-save their databases after upgrading so the new kdf can be used. This will not overwrite the old files, so they’ll need to be deleted manually.
Replaced usage of the async switch coroutine with asyncio.sleep because it was not allowing tasks to switch as it was designed to. Many improvements were made related to this change to make the package behave better in async contexts.
Removed the private method in the database classes which held a reference to the root salt. It’s now held in a private attribute. This change simplifies the code a bit & allows instances to be pickleable.
The atimeout & timeout chainable Comprende generator methods can now stop the generators’ executions mid-iteration. They run them in separate async tasks or thread pools, respectively, to acheive this.
The await_on & wait_on generators now restart their timeout counters after every successful iteration that detected a new value in their queue. The delay keyword argument was changed to probe_frequency, a keyword-only argument.
Removed the package’s dependency on the aioitertools package.
Made the sympy package an optional import. If any of its functionalities are used by the user, the package is only then imported & this is done automatically.
Various streamlining efforts were made to the imports & entropy initialization to reduce the package’s import & startup time.
Minor Changes
Fixes of various typos, docstrings & tutorials.
Various cleanups, refactorings & efficiency improvements.
Added new tests for detecting malformed or modified ciphertexts.
Removed extraneous functions in generics.py.
Add a UNIFORM_PRIME_512 value to __datasets.py for use in the Hasher.mask_byte_order & Hasher.amask_byte_order methods. Those methods were also altered to produce more uniform looking results. The returned masked values are now also 64 bytes by default.
Added an automate_key_use keyword-only boolean argument to the init for the OneTimePad, Keys & AsyncKeys classes. It can be toggled to stop the classes from overwriting class methods so they automatically read the instance’s key attribute. This optionally speeds up instantiation by an order of magnitude at the cost of convenience.
Fixed asynchs.Threads class’ wrongful use of a multiprocessing Manager.list object instead of a regular list.
Changed the _delay keyword-only argument in Processes & Threads classes’ methods to probe_freqeuncy so users can specify how often results will be checked for after firing off a process, thread, or associated pool submission.
Now the asubmit & submit methods in Processes & Threads can accept keyword arguments.
Added agather & gather methods to the Threads & Processes classes. They receive any number of functions, & args &/or kwargs to pass to those functions when submitting them to their associated pools.
Changed the runsum instance IDs from hex strings to bytes & cleaned up the instance caching & cleaning logic.
Altered & made private the asalted_multiply & salted_multiply functions in the randoms.py module.
Started a new event loop specific to the randoms.py module which should prevent the RuntimeError when random_number_generator is called from within the user’s running event loop.
Added a ValueError check to the (a)cspr(b/n)g functions in randoms.py. This will allow simultaneously running tasks to request entropy from the function by returning a result from a newly instantiated generator object.
Added checks in the *_encipher & *_decipher generators to help assure users correctly declare the mode for their StreamHMAC validator instances.
Fixed the __len__ function in the database classes to count the number of tags in the database & exclude their internal maintenaince files.
The TimeoutError raised after decrypting a ciphertext with an expired timestamp now contains the seconds it has exceeded the ttl in a value attribute.
The timestamp used to sign the package now displays the day of signing instead of the second of signing.
The (a)sum_sha_* & (a)sum_passcrypt generators were altered to reapply the supplied salt on every iteration.
Stabilized the usability of the stop keyword-only argument in the adata & data generators. It now directly decides the total number of elements in a sequence allowed to be yielded.
Changes for version 0.18.0
Major Changes
Security Patch: Rewrote the HMAC-like creation & authentication process for all of the package’s ciphers. Now, the *_encipher & *_decipher Comprende generators must be passed a validator object to hash the ciphertext as it’s being created / decrypted. The StreamHMAC class was created for this purpose. It’s initalized with the user’s long-term key, the ephemeral salt & the pid value. The pid value can now effectively be used to validate additional data. These changes force the package’s cipher to be used as an AEAD cipher.
Security Patch: The package’s *_hmac hash functions & the Comprende class’ hash generators were rewritten to prepend salts & keys to data prior to hashing instead of appending. This is better for several important reasons, such as: reducing the amortizability of costs in trying to brute-force hashes, & more closely following the reasoning behind the HMAC spec even though sha3 has a different security profile.
Algorithm Patch: The akeys, keys, abytes_keys, & bytes_keys algorithms have been patched to differentiate each iteration’s two sha3_512 hashes from one another in perpetuity. They contained a design flaw which would, if both sha3_512 objects landed upon the same 1600-bit internal state, then they would produce the same keystreams from then on. This change in backwards incompatible. This flaw is infeasible to exploit in practice, but since the package’s hashes & ciphertext validations were already channging this release, there was no reason to not fix this flaw so that it’s self-healing if they ever do land on the same internal states.
The Passcrypt class & its algorithm were made more efficient to better equalize the cost for users & adversaries & simplifies the algorithm. Any inefficiencies in an implementation would likely cause the adversary to be able to construct optimized implementations to put users at an even greater disadvantage at protecting their inputs to the passcrypt algorithm. It used the sum_sha_256 hash function internally, & since it was also changing in a non-backwards compatible way with this update, it was the best time to clean up the implementation.
Updated the package’s description & its docstrings that refer to the package’s cipher as an implementation of the one-time-pad. It’s not accurate since the package uses pseudo-random hash functions to produce key material. Instead, the package’s goal is to create a pseudo-one-time-pad that’s indistinguishable from a one-time-pad. The OneTimePad class will keep its name for succinctness.
New amake_token, make_token, aread_token & read_token class & instance methods added to the OneTimePad class. These tokens are urlsafe base64 encoded, are encrypted, authenticated & contain timestamps that can enforce a time-to-live for each token.
Non-backwards compatible changes to the database classes’ filenames, encryption keys & HMACs. The *_hmac hash functions that the databases rely on were changing with this update, so additionally the filenames table used to encode the filenames was switched from the BASE_36_TABLE to the BASE_38_TABLE. Both tables are safe for uri’s across all platforms, but the new table can encode information slightly more efficiently.
Major refactorings & signature changes across the package to make passing keys & salts to *_hmac functions & the Comprende class’ hash generators explicit.
Removed the of keyword argument from all of the Comprende class’ generators. It was overly complicating the code, & was not entirely clear or useful for settings outside of the tags & atags generators.
Removed pybase64 from the package & its dependencies list. The built-in python base64 module works just fine.
Sorted the WORDS_LIST, ASCII_ALPHANUMERIC, & BASE_64_TABLE datasets.
The salt & asalt functions have been renamed to generate_salt & agenerate_salt for clarity’s sake, & to reduce naming collisions.
Added another redundancy to the arandom_number_generator & random_number_generator functions. Now the async tasks it prepares into a list are pseudo-randomly shuffled before being passed into asyncio.gather.
Minor Changes
Added a logo image to the package.
Separated the FAQ section from PREADME.rst.
The primes & bits datasets are now represented in hex in the source code.
Added a BASE_38_TABLE dataset to the package.
The database classes now fill an ephemeral dictionary of filenames that couldn’t be used to successfully load a tag file, available from within the _corrupted_files attribute.
The Comprende class’ acache_check & cache_check context manager methods are now called aauto_cache & auto_cache.
Added new bytes_count & abytes_count generators to generics.py module which increment each iteration & yield the results as bytes.
Removed the akeypair & keypair functions from the package. Their successors are the asingle_use_key & single_use_key methods in the AsyncKeys & Keys classes. The attempt is to clarify & put constraints on the interface for creating a bundle of key material that has a single-use-only salt attached, as well as the pid value.
Moved ciphertext encoding functions into the BytesIO class from the global generics.py module.
Split PrimeGroups into two classes, one higher-level class by the same name & a BasePrimeGroups class. The former also has some added functionality for masking the order of bytes in a sequence using an modular exponentiation.
The Hasher class now has functionality added to mask the order of a bytes sequence with a modular multiplication.
Fixed the name of the project in the attribution lines in several source files.
Reconciled tests with the major changes in this release.
The old identity key for the package that was signed by the gnupg identity key was shredded & replaced with a new signed key.
Several bug fixes to the setup.py automated code signing.
Changes for version 0.17.0
Major Changes
Security Patch: The HMAC verifiers on ciphertexts did not include the salt or pid values when deriving the HMAC. This associated data can therefore be changed to cause a party to decrypt a past ciphertext with a salt or pid of an attacker’s choosing. This is a critical vulnerability & it is highly recommended all users update. The fix is to hash the ciphertext, salt & pid together & sending that hash into the validator to have the HMAC created / tested. This change will cause all prior ciphertexts to be marked invalid by the validator.
Refactored the names of the Comprende cipher methods to better communicate their intended use as lower level tools that cannot be used on their own to obtain authenticated, CCA or CPA secure encryption.
Added more comprehensive tests for X25519 & Ed25519 classes, as well as the protocols that utilize the X25519 ecdh exchange. Fixed some bugs in the process.
X25519 instances that contain a secret key now have access to protocol methods which automatically pass their key in as a keyword argument. This simplifies their usage further.
Incorporated the new Hasher class into the package’s random number generator to improve its entropy production.
Minor Changes
Various fixes to typos, docstrings & tutorials.
New tutorials & docs added.
Changed the default table in ByteIO ‘s json_to_ascii, ajson_to_ascii, ascii_to_json & aascii_to_json to the URL_SAFE_TABLE to facilitate the creation of urlsafe_tokens.
Removed all code in the Ropake class that was used to create a default database to store a default salt for users. All of that functionality is expected to be handled by the database classes’ token & profile creation tools.
Fixed bug in package signing script that called hex from a string.
Updated the package signing script to include these metadata in the signatures of the ephemeral keys: name of the package, version, the date in seconds.
Added metadata to the setup.cfg file.
Make passcrypt objects available from the keygens module.
Add more consistent ability within Ropake class to specify a time-to-live for protocol messages.
Added check to make sure instances of X25519 & Ed25519 are not trying to import a new secret key once they already have one. This won’t be allowed in favor of creating a new object for a new secret key.
Fixed bug in database classes’ bytes ciphers which called themselves recursively instead of calling the global functions of the same name.
Changes for version 0.16.0
Major Changes
All Database & AsyncDatabase filenames have been converted to base36 to aid in making the manifest files & the databases as a whole more space efficient. These changes are not backwards compatible.
More work was done to clean up the databases & make them more efficient, as well as equalize the sizes of the database files to mitigate leaking metadata about what they might contain.
Added new X25519 & Ed25519 classes that greatly simplify the usage of the cryptography module’s 25519 based tools. They also help organize the codebase better – where Ropake was holding onto all of the asymmetric tooling even though those tools were not part of the Ropake protocol.
New base & helper Asymmetric25519 & BaseEllipticCurve classes were added as well to facilitate the reorganization.
Many methods in Ropake were turned private to simplify & clean up the interface so its intended use as a protocol is more clear for users.
Added the time-to-live functionality to Ropake decryption functions. The TIMEOUT attribute on the class can also be changed to import a global time-to-live for all Ropake ciphertexts.
Removed all nc_ hash functions from the package/generics.py module.
The Namespace class now has a keys method so that namespaces can be unpacked using star-star syntax.
Because of the ongoing failures of gnupg, we are moving away from signing our packages with gnupg. Our new Ed25519 keys will be from the cryptography package, & we’ll sign those with our gnupg key as a secondary form of attestation. Our package signing will be automated in the setup.py file & the methods we use will be transparent in the code. The new signatures for each package version will be placed in the file SIGNATURES.txt.
Minor Changes
Many fixes & additions to docstrings & tutorials.
Massive refactorings, cleanups & typo fixes across the library, especially in the database classes, Ropake & the ciphers module.
Added comprehensive functional tests for the Ropake class.
Added BASE_36_TABLE to the commons module.
Fixed metadata issues in setup.py that caused upload issues to pypi.
The generate_profile, load_profile, agenerate_profile & aload_profile database methods now accept arbitrary keyword arguments that get passed into the database’s __init__ constructor.
username & password are now required keyword-only arguments to the agenerate_profile_tokens & generate_profile_tokens classmethods.
The aload & load database methods now take a manifest kwarg that when toggled True will also refresh the manifest file from disk.
Now when a database object is ordered to delete itself, the entirety of the instance’s caches & attribute values are cleared & deleted.
Filled out the references to strong key generators & protocols in the keygens module.
Changes for version 0.15.0
Major Changes
Security Patch: The previous update left the default salt stored by the Ropake class on the user filesystem as an empty string for new files that were created since the asalt & salt functions were switched to producing 256-bit values instead of 512-bits. This bug has now been fixed.
An 8 byte timestamp is now prepended to each plaintext during the padding step. The decryption functions now take a ttl kwarg which will measure & enforce a time-to-live for ciphertexts under threat of TimeoutError.
Added new profile feature to the database classes. This standardizes & simplifies the process for users to open databases using only low-entropy “profile” information such as username, password, *credentials & an optional salt a user may have access to. The new agenerate_profile_tokens, generate_profile_tokens, agenerate_profile, generate_profile, aprofile_exists, profile_exists, aload_profile, load_profile, adelete_profile & delete_profile functions are the public part of this new feature.
Some more database class attributes have been turned private to clean up the api.
Fixed typo in __exit__ method of Database class which referenced a method which had its name refactored, leading to a crash.
Shifted the values in the primes dictionary such that the key for each element in the dictionary is the exclusive maximum of each prime in that element. Ex: primes[512][-1].to_bytes(64, “big”) is now valid. Whereas before, primes[512] was filled with primes that were 64 bytes and 1 bit long, making them 65 byte primes. This changes some of the values of constants in the package & therefore some values derived from those constants.
Slimmed down the number of elements in the primes & bits dictionaries, reducing the size of the package a great deal. primes now contains two primes in each element, the first is the minimum prime of that bit length, the latter the maximum.
Added URLSAFE_TABLE to the package.
Made salt & pid & ttl keyword only arguments in key generators & encryption / decryption functions, further tighening up the api.
Minor Changes
Added this_second function to asynchs module for integer time.
Added apadding_key, padding_key, aplaintext_stream & plaintext_stream functions to the ciphers module.
Added apadding_key, padding_key to the keygens module & AsyncKeys & Keys classes.
Added axi_mix, xi_mix, acheck_timestamp, check_timestamp, to the generics module.
Added acsprbg, csprbg, asalt, salt, apadding_key, padding_key, aplaintext_stream & plaintext_stream functions to OneTimePad class as staticmethod & instance methods.
Added acheck_timestamp & check_timestamp functions to the BytesIO class.
Added adeniable_filename & deniable_filename to the paths module.
Removed check for falsey data in encryption functions. Empty data is & should be treated as valid plaintext.
Various refactorings, docstring fixes & efficiency improvements.
Added some new tests for database profiles.
Changes for version 0.14.0
Major Changes
Security patch: The apad_bytes, pad_bytes, adepad_bytes & depad_bytes functions were changed internally to execute in a more constant time. The variations were small for 256-byte buffers (the default), but can grow very wide with larger buffers. The salt in the package’s encryption utilities is now used to derive the plaintext’s padding, making each padding unique.
Unified the types of encodings the library’s encryption functions utilize for producing ciphertext. This includes databases. They now all use the LIST_ENCODING. This greatly increases the efficiency of the databases’ encryption/decryption, save/load times. And this encoding is more space efficient. This change is backwards incompatible.
The LIST_ENCODING specification was also changed to produce smaller ciphertexts. The salt is no longer encrypted & included as the first 256 byte chunk of ciphertext. It is now packaged along with ciphertext in the clear & is restricted to being a 256-bit hex string.
The interfaces for the Database & AsyncDatabase were cleaned up. Many attributes & functions that were not intended as the public interface of the classes were made “private”. Also, the no longer used utilities for encrypting & decrypting under the MAP_ENCODING were removed.
Updated the abytes_xor, bytes_xor, axor & xor generators to shrink the size of the seed that’s fed into the keystream. This allows the one-time-pad cipher to be more cpu efficient.
Minor Changes
Fixed various typos, docstrings & tutorials that have no kept up with the pace of changes.
Various refactorings throughout.
The akeypair & keypair functions now produce a Namespace populated with a 512-bit hex key & a 256-bit hex salt to be more consistent with their intended use-case with the one-time-pad cipher.
Removed aencode_salt, encode_salt, adecode_salt & decode_salt functions since they are no longer used in conjunction with LIST_ENCODING ciphertexts.
Updated tests to recognize these changes.
Gave the OneTimePad class access to a BytesIO object under a new io attribute.
Changes for version 0.13.0
Major Changes
Security Patch: xor & axor functions that define the one-time-pad cipher had a vulnerability fixed that can leak <1-bit of plaintext. The issue was in the way keys were built, where the multiplicative products of two key segments were xor’d together. This lead to keys being slightly more likely to be positive integers, meaning the final bit had a greater than 1/2 probability of being a 0. The fix is accompanied with an overhaul of the one-time-pad cipher which is more efficient, faster, & designed with a better understanding of the way bytes are processed & represented. The key chunks now do not, & must not, surpass 256 bytes & neither should any chunk of plaintext output. Making each chunk deterministically 256 bytes allows for reversibly formatting ciphertext to & from bytes-like strings. These changes are backwards incompatible with prior versions of this package & are strongly recommended.
Added bytes_xor & abytes_xor functions which take in key generators which produce key segments of type bytes instead of hex strings.
AsyncDatabase & Database now save files in bytes format, making them much more efficient on disk space. They use the new BytesIO class in the generics module to transparently convert to & from json & bytes. This change is also not backwards compatible.
Removed acipher, cipher, adecipher, decipher, aorganize_encryption_streams, organize_encryption_streams, aorganize_decryption_streams, organize_decryption_streams, aencrypt, encrypt, adecrypt, decrypt, asubkeys & subkeys generators from the ciphers module & package to slim down the code, remove repetition & focus on the cipher tools that include hmac authentication.
Removed deprecated diffie-hellman methods in Ropake class.
Removed the static power10 dictionary from the package.
The default secret salt for the Ropake class is now derived from the contents of a file that’s in the databases directory which is chmod’d to 0o000 unless needed.
Made aclient_message_key, client_message_key, aserver_message_key, & server_message_key Ropake class methods to help distinguish client-to-server & server-to-client message keys which prevents replay attacks on the one-message ROPAKE protocol.
Added protocol coroutines to the Ropake class which allow for easily engaging in 2DH & 3DH elliptic curve exchanges for servers & clients.
Efficiency improvements to the aseeder & seeder generator functions in the randoms module. This affects the acsprng & csprng objects & all the areas in the library that utilize those objects.
Changed the repr behavior of Comprende instances to redact all args & kwargs by default to protect cryptographic material from unintentionally being displayed on user systems. The repr can display full contents by calling the enable_debugging method of the DebugControl class.
All generator functions decorated with comprehension are now given a root attribute. This allows direct access to the function without needing to instantiate or run it as a Comprende object. This saves a good deal of cpu & time in the overhead that would otherwise be incurred by the class. This is specifically more helpful in tight &/or lower-level looping.
Minor Changes
Various refactorings across the library.
Fixed various typos, bugs & inaccurate docstrings throughout the library.
Add chown & chmod functions to the asynchs.aos module.
Now makes new multiprocessing.Manager objects in the asynchs.Processes & asynchs.Threads classes to avoid errors that occur when using a stale object whose socket connections are closed.
Changed Ropake class’ adb_login & db_login methods to adatabase_login_key & database_login_key. Also, fix a crash bug in those methods.
Changed Ropake class’ aec25519_pub, ec25519_pub, aec25519_priv & ec25519_priv methods to aec25519_public_bytes, ec25519_public_bytes, aec25519_private_bytes & ec25519_private_bytes.
Added low-level private methods to Ropake class which do derivation & querying of the default class key & salt.
Behavior changes to the ainverse_int & inverse_int functions in the generics module to allow handling bases represented in str or bytes type strings.
Behavior & name changes to the abinary_tree & binary_tree functions in the generics module to abuild_tree & build_tree. They now allow making uniform trees of any width & depth, limited only by the memory in a user’s machine.
Provided new acsprbg & csprbg objects to the library that return 512-bits of cryptographically secure pseudo-random bytes type strings. They are made by the new abytes_seeder & bytes_seeder generators.
The csprng, acsprng, csprbg & acsprbg objects were wrapped in functions that automatically restart the generators if they’re stalled / interrupted during a call. This keeps the package from melting down if it can no longer call the CSPRNGs for new entropy.
Cleaned up & simplified table_key functions in the keygens module.
Changed the output of asafe_symm_keypair & safe_symm_keypair functions to contain bytes values not their hex-only representation. Also removed these functions from the main imports of the package since they are slow & their main contribution is calling arandom_number_generator & random_number_generator to utilize a large entropy pool when starting CSPRNGs.
Added new values to the bits dictionary.
Added apad_bytes, pad_bytes, adepad_bytes & depad_bytes functions which use shake_256 to pad/depad plaintext bytes to & from multiples of 256 bytes. They take in a key to create the padding. This method is intended to also aid in protecting against padding oracle attacks.
Changes for version 0.12.0
Major Changes
The OPAKE protocol was renamed to ROPAKE, an acronym for Ratcheting Opaque Password Authenticated Key Exchange. This change was necessary since OPAKE is already a name for an existing PAKE protocol. This change also means the Opake class name was changed to Ropake.
The Ropake class’ registration algorithm was slightly modified to use the generated Curve25519 shared_key an extra time in the key derivation process. This shouldn’t break any currently authenticated sessions.
The asyncio_contextmanager package is no longer a listed dependency in setup.py. The main file from that package was copied over into the /aiootp directory in order to remove the piece of code that caused warnings to crop up when return values were retrieved from async generators. This change will put an end to this whack-a-mole process of trying to stop the warnings with try blocks scattered about the codebase.
Added asave_tag, save_tag, asave_file & save_file methods to the database classes so that specific entries can be saved to disk without having to save the entire database which is much more costly. The manifest file isn’t saved to disk when these methods are used, so if a tag file isn’t already saved in the database, then the saved files will not be present in the manifest or in the cache upon subsequent loads of the database. The saved file will still however be saved on the filesystem, though unbeknownst to the database instance.
The Namespace class now redacts all obvious key material in instance repr’s, which is any 64+ hex character string, or any number with 64+ decimal digits.
Removed the experimental recursive value retrieval within Comprende’s __aexamine_sent_exceptions & __examine_sent_exceptions methods. This change leads to more reliable & faster code, in exchange for an unnecessary feature being removed.
Bug fix of the auuids & uuids methods by editing the code in the asyncio_contextmanager dependency & using the patched package instead of the comprehension decorator for the arelay & relay methods of Comprende. Their internal algorithms was also updated to be simpler, but are incompatible with the outputs of past versions of these methods.
Minor Changes
Various refactorings & documentation additions / modifications throughout the library.
Various small bug fixes.
The shared keys derived from the Ropake protocol are now returned in a Namespace object instead of a raw dictionary, which allows the values to be retrieved by dotted &/or bracketed lookup.
The atest_hmac & test_hmac algorithms / methods were made more efficient & were refactored. Now they call atime_safe_equality & time_safe_equality internally, which are new methods that can apply the non-constant time but randomized timing comparisons on any pairs of values.
Changes for version 0.11.0
Major Changes
The Opake protocol was made greatly more efficient. This was done by replacing the diffie-hellman verifiers with a hash & xor commit & reveal system. Most hashing was made more efficient my using quicker & smaller sha_512 function instead of nc_512, & streamlining the protocol.
The Opake.client & Opake.client_registration methods now take an instantiated client database instead of client credentials which improves security, efficiency & usability. This change reduces the amount of exposure received by user passwords & other credentials. It also simplifies usage of the protocol by only needing to carry around a database instead of a slew of credentials, which is also faster, since the credentials are passed through the cpu & memory hard passcrypt function everytime to open the database.
Minor Changes
Heavy refactorings & documentation additions / modifications of the Opake class. Removed the Opake.ainit_database & Opake.init_database methods, & made the salt default argument parameter in Opake.aclient_database, Opake.client_database, Opake.adb_login & Opake.db_login into a keyword only argument so any extra user defined credentials are able to be passed without specifying a salt.
The decorators for the Comprende.arelay & Comprende.relay methods were changed from @asyncio_contextmanager.async_contextmanager to @comprehension() to stop that package from raising exceptions when we retrieve return values from async generators.
Changes for version 0.10.1
Major Changes
Added Processes & Threads classes to asynchs.py which abstract spawning & getting return values from async & sync functions intended to be run in threads, processes or pools of the former types. This simplifies & adds time control to usages of processes & threads throughout the library.
Reduced the effectiveness of timing analysis of the modular exponentiation in the Opake class’ verifiers by making the process return values only after discrete intervals of time. Timing attacks on that part of the protocol may still be viable, but should be significantly reduced.
Bug fix in Comprende which should take care of warnings raised from the aiocontext package when retrieving async generator values by raising UserWarning within them.
Minor Changes
Heavy refactorings of the Opake class.
Various refactorings & cleanups around the package.
Further add return_exceptions=True flag to gather calls in ciphers.py.
Added is_registration & is_authentication which take a client hello message that begin the Opake protocol, & return False if the message is not either a registration or authentication message, respectively, & return "Maybe" otherwise, since these functions can’t determine without running the protocol whether or not the message is valid.
Changes for version 0.10.0
Major Changes
Added a new oblivious, one-message, password authenticated key exchange protocol class in aiootp.ciphers.Opake. It is a first attempt at the protocol, which works rather well, but may be changed or cleaned up in a future update.
Added the cryptography package as a dependency for elliptic curve 25519 diffie-hellman key exchange in the Opake protocol.
Fix buggy data processing functions in generics.py module.
Added silent flag to AsyncDatabase & Database methods, which allows their instances to finish initializing even if a file is missing from the filesystem, normally causing a FileNotFoundError. This makes trouble-shooting corrupted databases easier.
Added new aiootp.paths.SecurePath function which returns the path to a unique directory within the database’s default directory. The name of the returned directory is a cryptographic value used to create & open the default database used by the Opake class to store the cryptographic salt that secures the class’ client passwords. It’s highly recommended to override this default database by instantiating the Opake class with a custom user-defined key. The instance doesn’t need to be saved, since all the class’ methods are either class or static methods. The __init__ method only changes the class’ default database to one opened with the user-defined key &/or directory kwargs, & should really only be done once at the beginning of an application.
Minor Changes
Various refactorings & cleanups around the package.
Added Comprende class feature to return the values from even the generators within an instance’s arguments. This change better returns values to the caller from chains of Comprende generators.
Fixed commons.BYTES_TABLE missing values.
Added commons.DH_PRIME_4096_BIT_GROUP_16 & commons.DH_GENERATOR_4096_BIT_GROUP_16 constants for use in the Opake protocol’s public key verifiers.
Added other values to the commons.py module.
Added new very large no-collision hash functions to the generics.py module used to xor with diffie-hellman public keys in the Opake class.
Added new wait_on & await_on Comprende generators to generics.py which waits for a queue or container to be populated & yields it whenever it isn’t empty.
Changes for version 0.9.3
Major Changes
Speed & efficiency improvements in the Comprende class & azip.
Minor Changes
Various refactorings & code cleanups.
Added apop & pop Comprende generators to the library.
Switched the default character table in the ato_base, to_base, afrom_base, & from_base chainable generator methods from the 62 character ASCII_ALPHANUMERIC table, to the 95 character ASCII_TABLE.
Made the digits generators in randoms.py automatically create a new cryptographically secure key if a key isn’t passed by a user.
Some extra data processing functions added to generics.py.
Changes for version 0.9.2
Major Changes
Added passcrypt & apasscrypt instance methods to OneTimePad, Keys, & AsyncKeys classes. They produce password hashes that are not just secured by the salt & passcrypt algorithm settings, but also by their main symmetric instance keys. This makes passwords infeasible to crack without also compromising the instance’s 512-bit key.
Minor Changes
Further improvements to the random number generator in randoms.py. Made its internals less sequential thereby raising the bar of work needed by an attacker to successfully carry out an order prediction attack.
Added checks in the Passcrypt class to make sure both a salt & password were passed into the algorithm.
Switched PermissionError exceptions in Passcrypt._validate_args to ValueError to be more consistent with the rest of the class.
Documentation updates / fixes.
Changes for version 0.9.1
Minor Changes
Now any falsey values for the salt keyword argument in the library’s keys, akeys, bytes_keys, abytes_keys, subkeys, & asubkeys infinite keystream generators, & other functions around the library, will cause them to generate a new cryptographically secure pseudo-random value for the salt. It formerly only did this when salt was None.
The seeder & aseeder generators have been updated to introduce 512 new bits of entropy from secrets.token_bytes on every iteration to ensure that the CSPRNG will produce secure outputs even if its internal state is somehow discovered. This also allows for simply calling the CSPRNG is enough, there’s no longer a strong reason to pass new entropy into it manually, except to add even more entropy as desired.
Made size the last keywordCHECKSUMS.txt argument in encrypt & aencrypt to better mirror the signatures for rest of the library.
Added token_bits & atoken_bits functions to randoms.py which are renamings of secrets.randbits.
Refactored & improved the security og randoms.py’s random number generator.
Changes for version 0.9.0
Major Changes
Added hmac codes to ciphertext for the following functions: json_encrypt, ajson_encrypt, bytes_encrypt, abytes_encrypt, Database.encrypt & AsyncDatabase.aencrypt. This change greatly increases the security of ciphertext by ensuring it hasn’t been modified or tampered with maliciously. One-time pad ciphertext is maleable, so without hmac validation it can be changed to successfully allow decryption but return the wrong plaintext. These functions are the highest level abstractions of the library for encryption/decryption, which made them excellent targets for this important security update. As well, it isn’t easily possible for the library to provide hmac codes for generators that produce ciphertext, because the end of a stream of ciphertext isn’t known until after the results have left the scope of library code. So users will need to produce their own hmac codes for generator ciphertext unless we find an elegant solution to this issue. These functions now all return dictionaries with the associated hmac stored in the "hmac" entry. The bytes functions formerly returned lists, now their ciphertext is available from the "ciphertext" entry. And, all database files will have an hmac attached to them now. These changes were designed to still be compatible with old ciphertexts but they’ll likely be made incompatible by the v0.11.x major release.
Only truthy values are now valid key keyword arguments in the library’s keys, akeys, bytes_keys, abytes_keys, subkeys, & asubkeys infinite keystream generators. Also now seeding extra entropy into csprng & acsprng when salt is falsey within them.
Only truthy values are now valid for password & salt arguments in apasscrypt, passcrypt & their variants.
Minor Changes
Updates to documentation & README.rst tutorials.
The kb, cpu, & hardness arguments in sum_passcrypt & asum_passcrypt chainable generator methods were switched to keyword only arguments.
Changes for version 0.8.1
Major Changes
Added sum_passcrypt & asum_passcrypt chainable generator methods to Comprende class. They cumulatively apply the passcrypt algorithm to each yielded value from an underlying generator with the passcrypt’d prior yielded result used as a salt. This allows making proofs of work, memory & space-time out of iterations of the passcrypt algorithm very simple.
Minor Changes
Various inaccurate docstrings fixed.
Various refactorings of the codebase.
Made kb, cpu, & hardness arguments into keyword only arguments in AsyncDatabase & Database classes.
The length keyword argument in functions around the library was changed to size to be consistent across the whole package. Reducing the cognitive burden of memorizing more than one name for the same concept.
Various efficiency boosts.
Edits to README.rst.
Added encode_salt, aencode_salt, decode_salt & adecode_salt functions to the library, which gives access to the procedure used to encrypt & decrypt the random salt which is often the first element produced in one-time pad ciphertexts.
Added cryptographically secure pseudo-random values as default keys in encryption functions to safeguard against users accidentally encrypting data without specifying a key. This way, such mistakes will produce ciphertext with an unrecoverable key, instead of without a key at all.
Changes for version 0.8.0
Major Changes
Fix test_hmac, atest_hmac functions in the keys & database classes. The new non-constant-time algorithm needs a random salt to be added before doing the secondary hmac to prevent some potential exotic forms of chosen plaintext/ciphertext attacks on the algorithm. The last version of the algorithm should not be used.
The Keys & AsyncKeys interfaces were overhauled to remove the persistance of instance salts. They were intended to be updated by users with the reset & areset methods, but that cannot be guaranteed easily through the class, so it is an inappropriate interface since reusing salts for encryption is completely insecure. The instances do still maintain state of their main encryption key, & new stateful methods for key generation, like mnemonic & table_key, have been added. The state & astate methods have been removed.
Gave OneTimePad instances new stateful methods from the ciphers.py module & keygens.py keys classes. Its instances now remember the main symmetric key behind the key property & automatically passes it as a keyword argument to the methods in OneTimePad.instance_methods.
Minor Changes
Update CHANGES.rst file with the updates that were not logged for v0.7.1.
BYTES_TABLE was turned into a list so that the byte characters can be retrieved instead of their ordinal numbers.
Changes for version 0.7.1
Major Changes
Fix a mistake in the signatures of passcrypt & apasscrypt. The args ``kb, cpu & hardness were changed into keyword only arguments to mitigate user mistakes, but the internal calls to those functions were still using positional function calls, which broke the api. This issue is now fixed.
Changes for version 0.7.0
Major Changes
Replaced usage of bare random module functions, to usage of an instance of random.Random to keep from messing with user’s settings on that module.
Finalized the algorithm for the passcrypt & apasscrypt functions. The algorithm is now provably memory & cpu hard with a wide security margin with adequate settings. The algorithm isn’t likely change with upcoming versions unless a major flaw is found.
The default value for the cpu argument in passcrypt & apasscrypt is now 3 & now directly determines how many hash iterations are done for each element in the memory cache. This provides much more responsiveness to users & increases the capacity to impact resource cost with less tinkering.
Switched the AsyncKeys.atest_hmac & Keys.test_hmac methods to a scheme which is not constant time, but which instead does not leak useful information. It does this by not comparing the hmacs of the data, but of a pair of secondary hmacs. The timing analysis itself is now dependant on knowledge of the key, since any conclusions of such an analysis would be unable correlate its findings with any supplied hmac without it.
Added test_hmac & atest_hmac to the database classes, & changed their hmac algorithm from sha3_512 to sha3_256.
Minor Changes
Various code cleanups, refactorings & speedups.
Several fixes to inaccurate documentation.
Several fixes to inaccurate function signatures.
Added mnemonic & amnemonic key generators to keygens.py with a wordlist 2048 entries long. A custom wordlist can also be passed in.
Minor changes in Comprende to track down a bug in the functions that use the asyncio_contextmanager package. It causes a warning when asking async generators to return (not yield) values.
Some refactoring of random_number_generator & arandom_number_generator.
Changes for version 0.6.0
Major Changes
Replaced the usage of os.urandom within the package with secrets.token_bytes to be more reliable across platforms.
Replaced several usages of random.randrange within randoms.py to calls to secrets.token_bytes which is faster & more secure. It now also seeds random module periodically prior to usage.
Changed the internal cache sorting algorithm of passcrypt & apasscrypt functions. The key function passed to list.sort(key=key) now not only updates the hashlib.sha3_512 proof object with each element in the cache, but with it’s own current output. This change is incompatible with previous versions of the functions. The key function is also trimmed down of unnecessary value checking.
The default value for the cpu argument in passcrypt & apasscrypt is now 40_000. This is right at the edge of when the argument begins impacting the cpu work needed to comptute the password hash when the kb argument is the default of 1024.
Switched the AsyncKeys.atest_hmac & Keys.test_hmac methods to a constant time algorithm.
Minor Changes
Various code cleanups, refactorings & speedups.
Added a concurrent.futures.ThreadPoolExecutor instance to the asynchs module for easily spinning off threads. It’s available under asynchs.thread_pool.
Added sort & asort chainable generator method to the Comprende class. They support sorting by a key sorting function as well.
Changed the name of asynchs.executor_wrapper to asynchs.wrap_in_executor.
Changed the name of randoms.non0_digit_stream, randoms.anon0_digit_stream, randoms.digit_stream & randoms.adigit_stream to randoms.non_0_digits, randoms.anon_0_digits, randoms.digits & randoms.adigits.
Several fixes to inaccurate documentation.
apasscrypt & Passcrypt.anew now use the synchronous version of the algorithm internally because it’s faster & it doesn’t change the parallelization properties of the function since it’s already run automatically in another process.
Added shuffle, ashuffle, unshuffle, & aunshuffle functions to randoms.py that reorder sequences pseudo-randomly based on their key & salt keyword arguments.
Fixed bugs in AsyncKeys & debuggers.py.
Added debugger & adebugger chainable generator methods to the Comprende class which benchmarks & inspects running generators with an inline syntax.
Changes for version 0.5.1
Major Changes
Fixed a bug in the methods auuids & uuids of the database classes that assigned to a variable within a closure that was nonlocal but which wasn’t declared non-local. This caused an error which made the methods unusable.
Added passcrypt & apasscrypt functions which are designed to be tunably memory & cpu hard password-based key derivation function. It was inspired by the scrypt protocol but internally uses the library’s tools. It is a first attempt at the protocol, it’s internal details will likely change in future updates.
Added bytes_keys & abytes_keys generators, which are just like the library’s keys generator, except they yield the concatenated sha3_512.digest instead of the sha3_512.hexdigest.
Added new chainable generator methods to the Comprende class for processing bytes, integers, & hex strings into one another.
Minor Changes
Various code cleanups.
New tests added to the test suite for passcrypt & apasscrypt.
The Comprende class’ alist & list methods can now be passed a boolean argument to return either a mutable list directly from the lru_cache, or a copy of the cached list. This list is used by the generator itself to yield its values, so wilely magic can be done on the list to mutate the underlying generator’s results.
Changes for version 0.5.0
Major Changes
Added interfaces in Database & AsyncDatabase to handle encrypting & decrypting streams (Comprende generators) instead of just raw json data. They’re methods called encrypt_stream, decrypt_stream, aencrypt_stream, & adecrypt_stream.
Changed the attribute _METATAG used by Database & AsyncDatabase to name the metatags entry in the database. This name is smaller, cleaner & is used to prevent naming collisions between user entered values & the metadata the classes need to organize themselves internally. This change will break databases from older versions keeping them from accessing their metatag child databases.
Added the methods auuids & uuids to AsyncDatabase & Database which return coroutines that accept potentially sensitive identifiers & turns them into salted size length hashes distinguished by a salt & a category.
Minor Changes
Various code & logic cleanups / speedups.
Refactorings of the Database & AsyncDatabase classes.
Various inaccurate docstrings fixed.
Changes for version 0.4.0
Major Changes
Fixed bug in aiootp.abytes_encrypt function which inaccurately called a synchronous Comprende end-point method on the underlying async generator, causing an exception and failure to function.
Changed the procedures in akeys & keys that generate their internal key derivation functions. They’re now slightly faster to initialize & more theoretically secure since each internal state is fed by a seed which isn’t returned to the user. This encryption algorithm change is incompatible with the encryption algorithms of past versions.
Minor Changes
Various code cleanups.
Various inaccurate docstrings fixed.
Keyword arguments in Keys().test_hmac & AsyncKeys().atest_hmac had their order switched to be slightly more friendly to use.
Added documentation to README.rst on the inner workings of the one-time-pad algorithm’s implementation.
Made Compende.arandom_sleep & Compende.random_sleep chainable generator methods.
Changed the Compende.adelimit_resize & Compende.delimit_resize algorithms to not yield inbetween two joined delimiters in a sequence being resized.
Changes for version 0.3.1
Minor Changes
Fixed bug where a static method in AsyncDatabase & Database was wrongly labelled a class method causing a failure to initialize.
Changes for version 0.3.0
Major Changes
The AsyncDatabase & Database now use the more secure afilename & filename methods to derive the hashmap name and encryption streams from a user-defined tag internal to their aencrypt / adecrypt / encrypt / decrypt methods, as well as, prior to them getting called. This will break past versions of databases’ ability to open their files.
The package now has built-in functions for using the one-time-pad algorithm to encrypt & decrypt binary data instead of just strings or integers. They are available in aiootp.abytes_encrypt, aiootp.abytes_decrypt, aiootp.bytes_encrypt & aiootp.bytes_decrypt.
The Comprende class now has generators that do encryption & decryption of binary data as well. They are available from any Comprende generator by the abytes_encrypt, abytes_decrypt, bytes_encrypt & bytes_decrypt chainable method calls.
Minor Changes
Fixed typos and inaccuracies in various docstrings.
Added a __ui_coordination.py module to handle inserting functionality from higher-level to lower-level modules and classes.
Various code clean ups and redundancy eliminations.
AsyncKeys & Keys classes now only update their self.salt key by default when their areset & reset methods are called. This aligns more closely with their intended use.
Added arandom_sleep & random_sleep chainable methods to the Comprende class which yields outputs of generators after a random sleep for each iteration.
Added several other chainable methods to the Comprende class for string & bytes data processing. They’re viewable in Comprende.lazy_generators.
Added new, initial tests to the test suite.
Changes for version 0.2.0
Major Changes
Added ephemeral salts to the AsyncDatabase & Database file encryption procedures. This is a major security fix, as re-encryption of files with the same tag in a database with the same open key would use the same streams of key material each time, breaking encryption if two different versions of a tag file’s ciphertext stored to disk were available to an adversary. The database methods encrypt, decrypt, aencrypt & adecrypt will now produce and decipher true one-time pad ciphertext with these ephemeral salts.
The aiootp.subkeys & aiootp.asubkeys generators were revamped to use the keys & akeys generators internally instead of using their own, slower algorithm.
AsyncDatabase file deletion is now asynchronous by running the builtins.os.remove function in an async thread executor. The decorator which does the magic is available at aiootp.asynchs.executor_wrapper.
Minor Changes
Fix typos in __root_salt & __aroot_salt docstrings. Also replaced the hash(self) argument for their lru_cache & alru_cache with a secure hmac instead.
add gi_frame, gi_running, gi_code, gi_yieldfrom, ag_frame, ag_running, ag_code & ag_await properties to Comprende class to mirror async/sync generators more closely.
Remove ajson_encrypt, ajson_decrypt, json_encrypt, json_decrypt functions’ internal creation of dicts to contain the plaintext. It was unnecessary & therefore wasteful.
Fix docstrings in OneTimePad methods mentioning parent kwarg which is a reference to deleted, refactored code.
Fix incorrect docstrings in databases namestream & anamestream methods.
Added ASYNC_GEN_THROWN constant to Comprende class to try to stop an infrequent & difficult to debug RuntimeError when async generators do not stop after receiving an athrow.
Database tags are now fully loaded when they’re copied using the methods into_namespace & ainto_namespace.
Updated inaccurate docstrings in map_encrypt, amap_encrypt, map_decrypt & amap_decrypt OneTimePad methods.
Added acustomize_parameters async function to aiootp.generics module.
Various code clean ups.
Changes for version 0.1.0
Minor Changes
Initial version.
Major Changes
Initial version.
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