Mini Shell
# Copyright 2013 Donald Stufft and individual contributors
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
from typing import ClassVar, Generic, Optional, Type, TypeVar
import nacl.bindings
from nacl import encoding
from nacl import exceptions as exc
from nacl.encoding import Encoder
from nacl.utils import EncryptedMessage, StringFixer, random
class PublicKey(encoding.Encodable, StringFixer):
"""
The public key counterpart to an Curve25519 :class:`nacl.public.PrivateKey`
for encrypting messages.
:param public_key: [:class:`bytes`] Encoded Curve25519 public key
:param encoder: A class that is able to decode the `public_key`
:cvar SIZE: The size that the public key is required to be
"""
SIZE: ClassVar[int] = nacl.bindings.crypto_box_PUBLICKEYBYTES
def __init__(
self,
public_key: bytes,
encoder: encoding.Encoder = encoding.RawEncoder,
):
self._public_key = encoder.decode(public_key)
if not isinstance(self._public_key, bytes):
raise exc.TypeError("PublicKey must be created from 32 bytes")
if len(self._public_key) != self.SIZE:
raise exc.ValueError(
"The public key must be exactly {} bytes long".format(
self.SIZE
)
)
def __bytes__(self) -> bytes:
return self._public_key
def __hash__(self) -> int:
return hash(bytes(self))
def __eq__(self, other: object) -> bool:
if not isinstance(other, self.__class__):
return False
return nacl.bindings.sodium_memcmp(bytes(self), bytes(other))
def __ne__(self, other: object) -> bool:
return not (self == other)
class PrivateKey(encoding.Encodable, StringFixer):
"""
Private key for decrypting messages using the Curve25519 algorithm.
.. warning:: This **must** be protected and remain secret. Anyone who
knows the value of your :class:`~nacl.public.PrivateKey` can decrypt
any message encrypted by the corresponding
:class:`~nacl.public.PublicKey`
:param private_key: The private key used to decrypt messages
:param encoder: The encoder class used to decode the given keys
:cvar SIZE: The size that the private key is required to be
:cvar SEED_SIZE: The size that the seed used to generate the
private key is required to be
"""
SIZE: ClassVar[int] = nacl.bindings.crypto_box_SECRETKEYBYTES
SEED_SIZE: ClassVar[int] = nacl.bindings.crypto_box_SEEDBYTES
def __init__(
self,
private_key: bytes,
encoder: encoding.Encoder = encoding.RawEncoder,
):
# Decode the secret_key
private_key = encoder.decode(private_key)
# verify the given secret key type and size are correct
if not (
isinstance(private_key, bytes) and len(private_key) == self.SIZE
):
raise exc.TypeError(
(
"PrivateKey must be created from a {} "
"bytes long raw secret key"
).format(self.SIZE)
)
raw_public_key = nacl.bindings.crypto_scalarmult_base(private_key)
self._private_key = private_key
self.public_key = PublicKey(raw_public_key)
@classmethod
def from_seed(
cls,
seed: bytes,
encoder: encoding.Encoder = encoding.RawEncoder,
) -> "PrivateKey":
"""
Generate a PrivateKey using a deterministic construction
starting from a caller-provided seed
.. warning:: The seed **must** be high-entropy; therefore,
its generator **must** be a cryptographic quality
random function like, for example, :func:`~nacl.utils.random`.
.. warning:: The seed **must** be protected and remain secret.
Anyone who knows the seed is really in possession of
the corresponding PrivateKey.
:param seed: The seed used to generate the private key
:rtype: :class:`~nacl.public.PrivateKey`
"""
# decode the seed
seed = encoder.decode(seed)
# Verify the given seed type and size are correct
if not (isinstance(seed, bytes) and len(seed) == cls.SEED_SIZE):
raise exc.TypeError(
(
"PrivateKey seed must be a {} bytes long "
"binary sequence"
).format(cls.SEED_SIZE)
)
# generate a raw keypair from the given seed
raw_pk, raw_sk = nacl.bindings.crypto_box_seed_keypair(seed)
# construct a instance from the raw secret key
return cls(raw_sk)
def __bytes__(self) -> bytes:
return self._private_key
def __hash__(self) -> int:
return hash((type(self), bytes(self.public_key)))
def __eq__(self, other: object) -> bool:
if not isinstance(other, self.__class__):
return False
return self.public_key == other.public_key
def __ne__(self, other: object) -> bool:
return not (self == other)
@classmethod
def generate(cls) -> "PrivateKey":
"""
Generates a random :class:`~nacl.public.PrivateKey` object
:rtype: :class:`~nacl.public.PrivateKey`
"""
return cls(random(PrivateKey.SIZE), encoder=encoding.RawEncoder)
_Box = TypeVar("_Box", bound="Box")
class Box(encoding.Encodable, StringFixer):
"""
The Box class boxes and unboxes messages between a pair of keys
The ciphertexts generated by :class:`~nacl.public.Box` include a 16
byte authenticator which is checked as part of the decryption. An invalid
authenticator will cause the decrypt function to raise an exception. The
authenticator is not a signature. Once you've decrypted the message you've
demonstrated the ability to create arbitrary valid message, so messages you
send are repudiable. For non-repudiable messages, sign them after
encryption.
:param private_key: :class:`~nacl.public.PrivateKey` used to encrypt and
decrypt messages
:param public_key: :class:`~nacl.public.PublicKey` used to encrypt and
decrypt messages
:cvar NONCE_SIZE: The size that the nonce is required to be.
"""
NONCE_SIZE: ClassVar[int] = nacl.bindings.crypto_box_NONCEBYTES
_shared_key: bytes
def __init__(self, private_key: PrivateKey, public_key: PublicKey):
if not isinstance(private_key, PrivateKey) or not isinstance(
public_key, PublicKey
):
raise exc.TypeError(
"Box must be created from a PrivateKey and a PublicKey"
)
self._shared_key = nacl.bindings.crypto_box_beforenm(
public_key.encode(encoder=encoding.RawEncoder),
private_key.encode(encoder=encoding.RawEncoder),
)
def __bytes__(self) -> bytes:
return self._shared_key
@classmethod
def decode(
cls: Type[_Box], encoded: bytes, encoder: Encoder = encoding.RawEncoder
) -> _Box:
"""
Alternative constructor. Creates a Box from an existing Box's shared key.
"""
# Create an empty box
box: _Box = cls.__new__(cls)
# Assign our decoded value to the shared key of the box
box._shared_key = encoder.decode(encoded)
return box
def encrypt(
self,
plaintext: bytes,
nonce: Optional[bytes] = None,
encoder: encoding.Encoder = encoding.RawEncoder,
) -> EncryptedMessage:
"""
Encrypts the plaintext message using the given `nonce` (or generates
one randomly if omitted) and returns the ciphertext encoded with the
encoder.
.. warning:: It is **VITALLY** important that the nonce is a nonce,
i.e. it is a number used only once for any given key. If you fail
to do this, you compromise the privacy of the messages encrypted.
:param plaintext: [:class:`bytes`] The plaintext message to encrypt
:param nonce: [:class:`bytes`] The nonce to use in the encryption
:param encoder: The encoder to use to encode the ciphertext
:rtype: [:class:`nacl.utils.EncryptedMessage`]
"""
if nonce is None:
nonce = random(self.NONCE_SIZE)
if len(nonce) != self.NONCE_SIZE:
raise exc.ValueError(
"The nonce must be exactly %s bytes long" % self.NONCE_SIZE
)
ciphertext = nacl.bindings.crypto_box_afternm(
plaintext,
nonce,
self._shared_key,
)
encoded_nonce = encoder.encode(nonce)
encoded_ciphertext = encoder.encode(ciphertext)
return EncryptedMessage._from_parts(
encoded_nonce,
encoded_ciphertext,
encoder.encode(nonce + ciphertext),
)
def decrypt(
self,
ciphertext: bytes,
nonce: Optional[bytes] = None,
encoder: encoding.Encoder = encoding.RawEncoder,
) -> bytes:
"""
Decrypts the ciphertext using the `nonce` (explicitly, when passed as a
parameter or implicitly, when omitted, as part of the ciphertext) and
returns the plaintext message.
:param ciphertext: [:class:`bytes`] The encrypted message to decrypt
:param nonce: [:class:`bytes`] The nonce used when encrypting the
ciphertext
:param encoder: The encoder used to decode the ciphertext.
:rtype: [:class:`bytes`]
"""
# Decode our ciphertext
ciphertext = encoder.decode(ciphertext)
if nonce is None:
# If we were given the nonce and ciphertext combined, split them.
nonce = ciphertext[: self.NONCE_SIZE]
ciphertext = ciphertext[self.NONCE_SIZE :]
if len(nonce) != self.NONCE_SIZE:
raise exc.ValueError(
"The nonce must be exactly %s bytes long" % self.NONCE_SIZE
)
plaintext = nacl.bindings.crypto_box_open_afternm(
ciphertext,
nonce,
self._shared_key,
)
return plaintext
def shared_key(self) -> bytes:
"""
Returns the Curve25519 shared secret, that can then be used as a key in
other symmetric ciphers.
.. warning:: It is **VITALLY** important that you use a nonce with your
symmetric cipher. If you fail to do this, you compromise the
privacy of the messages encrypted. Ensure that the key length of
your cipher is 32 bytes.
:rtype: [:class:`bytes`]
"""
return self._shared_key
_Key = TypeVar("_Key", PublicKey, PrivateKey)
class SealedBox(Generic[_Key], encoding.Encodable, StringFixer):
"""
The SealedBox class boxes and unboxes messages addressed to
a specified key-pair by using ephemeral sender's keypairs,
whose private part will be discarded just after encrypting
a single plaintext message.
The ciphertexts generated by :class:`~nacl.public.SecretBox` include
the public part of the ephemeral key before the :class:`~nacl.public.Box`
ciphertext.
:param recipient_key: a :class:`~nacl.public.PublicKey` used to encrypt
messages and derive nonces, or a :class:`~nacl.public.PrivateKey` used
to decrypt messages.
.. versionadded:: 1.2
"""
_public_key: bytes
_private_key: Optional[bytes]
def __init__(self, recipient_key: _Key):
if isinstance(recipient_key, PublicKey):
self._public_key = recipient_key.encode(
encoder=encoding.RawEncoder
)
self._private_key = None
elif isinstance(recipient_key, PrivateKey):
self._private_key = recipient_key.encode(
encoder=encoding.RawEncoder
)
self._public_key = recipient_key.public_key.encode(
encoder=encoding.RawEncoder
)
else:
raise exc.TypeError(
"SealedBox must be created from a PublicKey or a PrivateKey"
)
def __bytes__(self) -> bytes:
return self._public_key
def encrypt(
self,
plaintext: bytes,
encoder: encoding.Encoder = encoding.RawEncoder,
) -> bytes:
"""
Encrypts the plaintext message using a random-generated ephemeral
keypair and returns a "composed ciphertext", containing both
the public part of the keypair and the ciphertext proper,
encoded with the encoder.
The private part of the ephemeral key-pair will be scrubbed before
returning the ciphertext, therefore, the sender will not be able to
decrypt the generated ciphertext.
:param plaintext: [:class:`bytes`] The plaintext message to encrypt
:param encoder: The encoder to use to encode the ciphertext
:return bytes: encoded ciphertext
"""
ciphertext = nacl.bindings.crypto_box_seal(plaintext, self._public_key)
encoded_ciphertext = encoder.encode(ciphertext)
return encoded_ciphertext
def decrypt(
self: "SealedBox[PrivateKey]",
ciphertext: bytes,
encoder: encoding.Encoder = encoding.RawEncoder,
) -> bytes:
"""
Decrypts the ciphertext using the ephemeral public key enclosed
in the ciphertext and the SealedBox private key, returning
the plaintext message.
:param ciphertext: [:class:`bytes`] The encrypted message to decrypt
:param encoder: The encoder used to decode the ciphertext.
:return bytes: The original plaintext
:raises TypeError: if this SealedBox was created with a
:class:`~nacl.public.PublicKey` rather than a
:class:`~nacl.public.PrivateKey`.
"""
# Decode our ciphertext
ciphertext = encoder.decode(ciphertext)
if self._private_key is None:
raise TypeError(
"SealedBoxes created with a public key cannot decrypt"
)
plaintext = nacl.bindings.crypto_box_seal_open(
ciphertext,
self._public_key,
self._private_key,
)
return plaintext
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