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# -*- coding: utf-8 -*-
# keys.py
# Copyright (C) 2013 LEAP
#
# This program is free software: you can redistribute it and/or modify
# it under the terms of the GNU General Public License as published by
# the Free Software Foundation, either version 3 of the License, or
# (at your option) any later version.
#
# This program 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 General Public License for more details.
#
# You should have received a copy of the GNU General Public License
# along with this program. If not, see <http://www.gnu.org/licenses/>.
"""
Abstact key type and encryption scheme representations.
"""
try:
import simplejson as json
except ImportError:
import json # noqa
import logging
import re
import time
from abc import ABCMeta, abstractmethod
from datetime import datetime
from leap.common.check import leap_assert
from twisted.internet import defer
from leap.keymanager.validation import ValidationLevel, toValidationLevel
logger = logging.getLogger(__name__)
#
# Dictionary keys used for storing cryptographic keys.
#
KEY_ADDRESS_KEY = 'address'
KEY_TYPE_KEY = 'type'
KEY_ID_KEY = 'key_id'
KEY_FINGERPRINT_KEY = 'fingerprint'
KEY_DATA_KEY = 'key_data'
KEY_PRIVATE_KEY = 'private'
KEY_LENGTH_KEY = 'length'
KEY_EXPIRY_DATE_KEY = 'expiry_date'
KEY_LAST_AUDITED_AT_KEY = 'last_audited_at'
KEY_REFRESHED_AT_KEY = 'refreshed_at'
KEY_VALIDATION_KEY = 'validation'
KEY_ENCR_USED_KEY = 'encr_used'
KEY_SIGN_USED_KEY = 'sign_used'
KEY_TAGS_KEY = 'tags'
#
# Key storage constants
#
KEYMANAGER_KEY_TAG = 'keymanager-key'
KEYMANAGER_ACTIVE_TAG = 'keymanager-active'
KEYMANAGER_ACTIVE_TYPE = '-active'
#
# key indexing constants.
#
TAGS_PRIVATE_INDEX = 'by-tags-private'
TYPE_ID_PRIVATE_INDEX = 'by-type-id-private'
TYPE_ADDRESS_PRIVATE_INDEX = 'by-type-address-private'
INDEXES = {
TAGS_PRIVATE_INDEX: [
KEY_TAGS_KEY,
'bool(%s)' % KEY_PRIVATE_KEY,
],
TYPE_ID_PRIVATE_INDEX: [
KEY_TYPE_KEY,
KEY_ID_KEY,
'bool(%s)' % KEY_PRIVATE_KEY,
],
TYPE_ADDRESS_PRIVATE_INDEX: [
KEY_TYPE_KEY,
KEY_ADDRESS_KEY,
'bool(%s)' % KEY_PRIVATE_KEY,
]
}
#
# Key handling utilities
#
def is_address(address):
"""
Return whether the given C{address} is in the form user@provider.
:param address: The address to be tested.
:type address: str
:return: Whether C{address} is in the form user@provider.
:rtype: bool
"""
return bool(re.match('[\w.-]+@[\w.-]+', address))
def build_key_from_dict(kClass, kdict):
"""
Build an C{kClass} key based on info in C{kdict}.
:param kdict: Dictionary with key data.
:type kdict: dict
:return: An instance of the key.
:rtype: C{kClass}
"""
try:
validation = toValidationLevel(kdict[KEY_VALIDATION_KEY])
except ValueError:
logger.error("Not valid validation level (%s) for key %s",
(kdict[KEY_VALIDATION_KEY], kdict[KEY_ID_KEY]))
validation = ValidationLevel.Weak_Chain
expiry_date = _to_datetime(kdict[KEY_EXPIRY_DATE_KEY])
last_audited_at = _to_datetime(kdict[KEY_LAST_AUDITED_AT_KEY])
refreshed_at = _to_datetime(kdict[KEY_REFRESHED_AT_KEY])
return kClass(
kdict[KEY_ADDRESS_KEY],
key_id=kdict[KEY_ID_KEY],
fingerprint=kdict[KEY_FINGERPRINT_KEY],
key_data=kdict[KEY_DATA_KEY],
private=kdict[KEY_PRIVATE_KEY],
length=kdict[KEY_LENGTH_KEY],
expiry_date=expiry_date,
last_audited_at=last_audited_at,
refreshed_at=refreshed_at,
validation=validation,
encr_used=kdict[KEY_ENCR_USED_KEY],
sign_used=kdict[KEY_SIGN_USED_KEY],
)
def _to_datetime(unix_time):
if unix_time != 0:
return datetime.fromtimestamp(unix_time)
else:
return None
def _to_unix_time(date):
if date is not None:
return int(time.mktime(date.timetuple()))
else:
return 0
#
# Abstraction for encryption keys
#
class EncryptionKey(object):
"""
Abstract class for encryption keys.
A key is "validated" if the nicknym agent has bound the user address to a
public key.
"""
__metaclass__ = ABCMeta
def __init__(self, address, key_id="", fingerprint="",
key_data="", private=False, length=0, expiry_date=None,
validation=ValidationLevel.Weak_Chain, last_audited_at=None,
refreshed_at=None, encr_used=False, sign_used=False):
self.address = address
self.key_id = key_id
self.fingerprint = fingerprint
self.key_data = key_data
self.private = private
self.length = length
self.expiry_date = expiry_date
self.validation = validation
self.last_audited_at = last_audited_at
self.refreshed_at = refreshed_at
self.encr_used = encr_used
self.sign_used = sign_used
def get_json(self):
"""
Return a JSON string describing this key.
:return: The JSON string describing this key.
:rtype: str
"""
expiry_date = _to_unix_time(self.expiry_date)
last_audited_at = _to_unix_time(self.last_audited_at)
refreshed_at = _to_unix_time(self.refreshed_at)
return json.dumps({
KEY_ADDRESS_KEY: self.address,
KEY_TYPE_KEY: self.__class__.__name__,
KEY_ID_KEY: self.key_id,
KEY_FINGERPRINT_KEY: self.fingerprint,
KEY_DATA_KEY: self.key_data,
KEY_PRIVATE_KEY: self.private,
KEY_LENGTH_KEY: self.length,
KEY_EXPIRY_DATE_KEY: expiry_date,
KEY_LAST_AUDITED_AT_KEY: last_audited_at,
KEY_REFRESHED_AT_KEY: refreshed_at,
KEY_VALIDATION_KEY: str(self.validation),
KEY_ENCR_USED_KEY: self.encr_used,
KEY_SIGN_USED_KEY: self.sign_used,
KEY_TAGS_KEY: [KEYMANAGER_KEY_TAG],
})
def get_active_json(self, address):
"""
Return a JSON string describing this key.
:param address: Address for wich the key is active
:type address: str
:return: The JSON string describing this key.
:rtype: str
"""
return json.dumps({
KEY_ADDRESS_KEY: address,
KEY_TYPE_KEY: self.__class__.__name__ + KEYMANAGER_ACTIVE_TYPE,
KEY_ID_KEY: self.key_id,
KEY_PRIVATE_KEY: self.private,
KEY_TAGS_KEY: [KEYMANAGER_ACTIVE_TAG],
})
def __repr__(self):
"""
Representation of this class
"""
return u"<%s 0x%s (%s - %s)>" % (
self.__class__.__name__,
self.key_id,
self.address,
"priv" if self.private else "publ")
#
# Encryption schemes
#
class EncryptionScheme(object):
"""
Abstract class for Encryption Schemes.
A wrapper for a certain encryption schemes should know how to get and put
keys in local storage using Soledad, how to generate new keys and how to
find out about possibly encrypted content.
"""
__metaclass__ = ABCMeta
def __init__(self, soledad):
"""
Initialize this Encryption Scheme.
:param soledad: A Soledad instance for local storage of keys.
:type soledad: leap.soledad.Soledad
"""
self._soledad = soledad
self._init_indexes()
def _init_indexes(self):
"""
Initialize the database indexes.
"""
leap_assert(self._soledad is not None,
"Cannot init indexes with null soledad")
def init_idexes(indexes):
deferreds = []
db_indexes = dict(indexes)
# Loop through the indexes we expect to find.
for name, expression in INDEXES.items():
if name not in db_indexes:
# The index does not yet exist.
d = self._soledad.create_index(name, *expression)
deferreds.append(d)
elif expression != db_indexes[name]:
# The index exists but the definition is not what expected,
# so we delete it and add the proper index expression.
d = self._soledad.delete_index(name)
d.addCallback(
lambda _:
self._soledad.create_index(name, *expression))
deferreds.append(d)
return defer.gatherResults(deferreds, consumeErrors=True)
self.deferred_indexes = self._soledad.list_indexes()
self.deferred_indexes.addCallback(init_idexes)
def _wait_indexes(self, *methods):
"""
Methods that need to wait for the indexes to be ready.
Heavily based on
http://blogs.fluidinfo.com/terry/2009/05/11/a-mixin-class-allowing-python-__init__-methods-to-work-with-twisted-deferreds/
:param methods: methods that need to wait for the indexes to be ready
:type methods: tuple(str)
"""
self.waiting = []
self.stored = {}
def restore(_):
for method in self.stored:
setattr(self, method, self.stored[method])
for d in self.waiting:
d.callback(None)
def makeWrapper(method):
def wrapper(*args, **kw):
d = defer.Deferred()
d.addCallback(lambda _: self.stored[method](*args, **kw))
self.waiting.append(d)
return d
return wrapper
for method in methods:
self.stored[method] = getattr(self, method)
setattr(self, method, makeWrapper(method))
self.deferred_indexes.addCallback(restore)
@abstractmethod
def get_key(self, address, private=False):
"""
Get key from local storage.
:param address: The address bound to the key.
:type address: str
:param private: Look for a private key instead of a public one?
:type private: bool
:return: A Deferred which fires with the EncryptionKey bound to
address, or which fails with KeyNotFound if the key was not
found on local storage.
:rtype: Deferred
"""
pass
@abstractmethod
def put_key(self, key, address):
"""
Put a key in local storage.
:param key: The key to be stored.
:type key: EncryptionKey
:param address: address for which this key will be active.
:type address: str
:return: A Deferred which fires when the key is in the storage.
:rtype: Deferred
"""
pass
@abstractmethod
def gen_key(self, address):
"""
Generate a new key.
:param address: The address bound to the key.
:type address: str
:return: The key bound to C{address}.
:rtype: EncryptionKey
"""
pass
@abstractmethod
def delete_key(self, key):
"""
Remove C{key} from storage.
:param key: The key to be removed.
:type key: EncryptionKey
:return: A Deferred which fires when the key is deleted, or which
fails with KeyNotFound if the key was not found on local
storage.
:rtype: Deferred
"""
pass
@abstractmethod
def encrypt(self, data, pubkey, passphrase=None, sign=None):
"""
Encrypt C{data} using public @{pubkey} and sign with C{sign} key.
:param data: The data to be encrypted.
:type data: str
:param pubkey: The key used to encrypt.
:type pubkey: EncryptionKey
:param sign: The key used for signing.
:type sign: EncryptionKey
:return: The encrypted data.
:rtype: str
"""
pass
@abstractmethod
def decrypt(self, data, privkey, passphrase=None, verify=None):
"""
Decrypt C{data} using private @{privkey} and verify with C{verify} key.
:param data: The data to be decrypted.
:type data: str
:param privkey: The key used to decrypt.
:type privkey: OpenPGPKey
:param verify: The key used to verify a signature.
:type verify: OpenPGPKey
:return: The decrypted data and if signature verifies
:rtype: (unicode, bool)
:raise DecryptError: Raised if failed decrypting for some reason.
"""
pass
@abstractmethod
def sign(self, data, privkey):
"""
Sign C{data} with C{privkey}.
:param data: The data to be signed.
:type data: str
:param privkey: The private key to be used to sign.
:type privkey: EncryptionKey
:return: The signed data.
:rtype: str
"""
pass
@abstractmethod
def verify(self, data, pubkey, detached_sig=None):
"""
Verify signed C{data} with C{pubkey}, eventually using
C{detached_sig}.
:param data: The data to be verified.
:type data: str
:param pubkey: The public key to be used on verification.
:type pubkey: EncryptionKey
:param detached_sig: A detached signature. If given, C{data} is
verified against this sdetached signature.
:type detached_sig: str
:return: signature matches
:rtype: bool
"""
pass
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