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Direktori : /lib/python3/dist-packages/paramiko/ |
Current File : //lib/python3/dist-packages/paramiko/ed25519key.py |
# This file is part of paramiko. # # Paramiko is free software; you can redistribute it and/or modify it under the # terms of the GNU Lesser General Public License as published by the Free # Software Foundation; either version 2.1 of the License, or (at your option) # any later version. # # Paramiko is distributed in the hope that it will be useful, but WITHOUT ANY # WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR # A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more # details. # # You should have received a copy of the GNU Lesser General Public License # along with Paramiko; if not, write to the Free Software Foundation, Inc., # 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. import bcrypt from cryptography.hazmat.backends import default_backend from cryptography.hazmat.primitives.ciphers import Cipher import nacl.signing from paramiko.message import Message from paramiko.pkey import PKey, OPENSSH_AUTH_MAGIC, _unpad_openssh from paramiko.py3compat import b from paramiko.ssh_exception import SSHException, PasswordRequiredException class Ed25519Key(PKey): """ Representation of an `Ed25519 <https://ed25519.cr.yp.to/>`_ key. .. note:: Ed25519 key support was added to OpenSSH in version 6.5. .. versionadded:: 2.2 .. versionchanged:: 2.3 Added a ``file_obj`` parameter to match other key classes. """ def __init__( self, msg=None, data=None, filename=None, password=None, file_obj=None ): self.public_blob = None verifying_key = signing_key = None if msg is None and data is not None: msg = Message(data) if msg is not None: self._check_type_and_load_cert( msg=msg, key_type="ssh-ed25519", cert_type="ssh-ed25519-cert-v01@openssh.com", ) verifying_key = nacl.signing.VerifyKey(msg.get_binary()) elif filename is not None: with open(filename, "r") as f: pkformat, data = self._read_private_key("OPENSSH", f) elif file_obj is not None: pkformat, data = self._read_private_key("OPENSSH", file_obj) if filename or file_obj: signing_key = self._parse_signing_key_data(data, password) if signing_key is None and verifying_key is None: raise ValueError("need a key") self._signing_key = signing_key self._verifying_key = verifying_key def _parse_signing_key_data(self, data, password): from paramiko.transport import Transport # We may eventually want this to be usable for other key types, as # OpenSSH moves to it, but for now this is just for Ed25519 keys. # This format is described here: # https://github.com/openssh/openssh-portable/blob/master/PROTOCOL.key # The description isn't totally complete, and I had to refer to the # source for a full implementation. message = Message(data) if message.get_bytes(len(OPENSSH_AUTH_MAGIC)) != OPENSSH_AUTH_MAGIC: raise SSHException("Invalid key") ciphername = message.get_text() kdfname = message.get_text() kdfoptions = message.get_binary() num_keys = message.get_int() if kdfname == "none": # kdfname of "none" must have an empty kdfoptions, the ciphername # must be "none" if kdfoptions or ciphername != "none": raise SSHException("Invalid key") elif kdfname == "bcrypt": if not password: raise PasswordRequiredException( "Private key file is encrypted" ) kdf = Message(kdfoptions) bcrypt_salt = kdf.get_binary() bcrypt_rounds = kdf.get_int() else: raise SSHException("Invalid key") if ciphername != "none" and ciphername not in Transport._cipher_info: raise SSHException("Invalid key") public_keys = [] for _ in range(num_keys): pubkey = Message(message.get_binary()) if pubkey.get_text() != "ssh-ed25519": raise SSHException("Invalid key") public_keys.append(pubkey.get_binary()) private_ciphertext = message.get_binary() if ciphername == "none": private_data = private_ciphertext else: cipher = Transport._cipher_info[ciphername] key = bcrypt.kdf( password=b(password), salt=bcrypt_salt, desired_key_bytes=cipher["key-size"] + cipher["block-size"], rounds=bcrypt_rounds, # We can't control how many rounds are on disk, so no sense # warning about it. ignore_few_rounds=True, ) decryptor = Cipher( cipher["class"](key[: cipher["key-size"]]), cipher["mode"](key[cipher["key-size"] :]), backend=default_backend(), ).decryptor() private_data = ( decryptor.update(private_ciphertext) + decryptor.finalize() ) message = Message(_unpad_openssh(private_data)) if message.get_int() != message.get_int(): raise SSHException("Invalid key") signing_keys = [] for i in range(num_keys): if message.get_text() != "ssh-ed25519": raise SSHException("Invalid key") # A copy of the public key, again, ignore. public = message.get_binary() key_data = message.get_binary() # The second half of the key data is yet another copy of the public # key... signing_key = nacl.signing.SigningKey(key_data[:32]) # Verify that all the public keys are the same... assert ( signing_key.verify_key.encode() == public == public_keys[i] == key_data[32:] ) signing_keys.append(signing_key) # Comment, ignore. message.get_binary() if len(signing_keys) != 1: raise SSHException("Invalid key") return signing_keys[0] def asbytes(self): if self.can_sign(): v = self._signing_key.verify_key else: v = self._verifying_key m = Message() m.add_string("ssh-ed25519") m.add_string(v.encode()) return m.asbytes() @property def _fields(self): if self.can_sign(): v = self._signing_key.verify_key else: v = self._verifying_key return (self.get_name(), v) def get_name(self): return "ssh-ed25519" def get_bits(self): return 256 def can_sign(self): return self._signing_key is not None def sign_ssh_data(self, data, algorithm=None): m = Message() m.add_string("ssh-ed25519") m.add_string(self._signing_key.sign(data).signature) return m def verify_ssh_sig(self, data, msg): if msg.get_text() != "ssh-ed25519": return False try: self._verifying_key.verify(data, msg.get_binary()) except nacl.exceptions.BadSignatureError: return False else: return True