# -*- coding: utf-8 -*-
# crypto.py
# Copyright (C) 2013, 2014 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 .
"""
Cryptographic utilities for Soledad.
"""
import os
import binascii
import hmac
import hashlib
import json
import logging
import multiprocessing
import threading
from pycryptopp.cipher.aes import AES
from pycryptopp.cipher.xsalsa20 import XSalsa20
from zope.proxy import sameProxiedObjects
from leap.soledad.common import soledad_assert
from leap.soledad.common import soledad_assert_type
from leap.soledad.common import crypto
from leap.soledad.common.document import SoledadDocument
logger = logging.getLogger(__name__)
MAC_KEY_LENGTH = 64
def _assert_known_encryption_method(method):
"""
Assert that we can encrypt/decrypt the given C{method}
:param method: The encryption method to assert.
:type method: str
:raise UnknownEncryptionMethodError: Raised when C{method} is unknown.
"""
valid_methods = [
crypto.EncryptionMethods.AES_256_CTR,
crypto.EncryptionMethods.XSALSA20,
]
try:
soledad_assert(method in valid_methods)
except AssertionError:
raise crypto.UnknownEncryptionMethodError
def encrypt_sym(data, key, method):
"""
Encrypt C{data} using a {password}.
Currently, the only encryption methods supported are AES-256 in CTR
mode and XSalsa20.
:param data: The data to be encrypted.
:type data: str
:param key: The key used to encrypt C{data} (must be 256 bits long).
:type key: str
:param method: The encryption method to use.
:type method: str
:return: A tuple with the initial value and the encrypted data.
:rtype: (long, str)
:raise AssertionError: Raised if C{method} is unknown.
"""
soledad_assert_type(key, str)
soledad_assert(
len(key) == 32, # 32 x 8 = 256 bits.
'Wrong key size: %s bits (must be 256 bits long).' %
(len(key) * 8))
_assert_known_encryption_method(method)
iv = None
# AES-256 in CTR mode
if method == crypto.EncryptionMethods.AES_256_CTR:
iv = os.urandom(16)
ciphertext = AES(key=key, iv=iv).process(data)
# XSalsa20
elif method == crypto.EncryptionMethods.XSALSA20:
iv = os.urandom(24)
ciphertext = XSalsa20(key=key, iv=iv).process(data)
return binascii.b2a_base64(iv), ciphertext
def decrypt_sym(data, key, method, **kwargs):
"""
Decrypt data using symmetric secret.
Currently, the only encryption method supported is AES-256 CTR mode.
:param data: The data to be decrypted.
:type data: str
:param key: The key used to decrypt C{data} (must be 256 bits long).
:type key: str
:param method: The encryption method to use.
:type method: str
:param kwargs: Other parameters specific to each encryption method.
:type kwargs: dict
:return: The decrypted data.
:rtype: str
:raise UnknownEncryptionMethodError: Raised when C{method} is unknown.
"""
soledad_assert_type(key, str)
# assert params
soledad_assert(
len(key) == 32, # 32 x 8 = 256 bits.
'Wrong key size: %s (must be 256 bits long).' % len(key))
soledad_assert(
'iv' in kwargs,
'%s needs an initial value.' % method)
_assert_known_encryption_method(method)
# AES-256 in CTR mode
if method == crypto.EncryptionMethods.AES_256_CTR:
return AES(
key=key, iv=binascii.a2b_base64(kwargs['iv'])).process(data)
elif method == crypto.EncryptionMethods.XSALSA20:
return XSalsa20(
key=key, iv=binascii.a2b_base64(kwargs['iv'])).process(data)
def doc_mac_key(doc_id, secret):
"""
Generate a key for calculating a MAC for a document whose id is
C{doc_id}.
The key is derived using HMAC having sha256 as underlying hash
function. The key used for HMAC is the first MAC_KEY_LENGTH characters
of Soledad's storage secret. The HMAC message is C{doc_id}.
:param doc_id: The id of the document.
:type doc_id: str
:param secret: The Soledad storage secret
:type secret: str
:return: The key.
:rtype: str
"""
soledad_assert(secret is not None)
return hmac.new(
secret[:MAC_KEY_LENGTH],
doc_id,
hashlib.sha256).digest()
class SoledadCrypto(object):
"""
General cryptographic functionality encapsulated in a
object that can be passed along.
"""
def __init__(self, soledad):
"""
Initialize the crypto object.
:param soledad: A Soledad instance for key lookup.
:type soledad: leap.soledad.Soledad
"""
self._soledad = soledad
def encrypt_sym(self, data, key,
method=crypto.EncryptionMethods.AES_256_CTR):
return encrypt_sym(data, key, method)
def decrypt_sym(self, data, key,
method=crypto.EncryptionMethods.AES_256_CTR, **kwargs):
return decrypt_sym(data, key, method, **kwargs)
def doc_mac_key(self, doc_id, secret):
return doc_mac_key(doc_id, self.secret)
def doc_passphrase(self, doc_id):
"""
Generate a passphrase for symmetric encryption of document's contents.
The password is derived using HMAC having sha256 as underlying hash
function. The key used for HMAC are the first
C{soledad.REMOTE_STORAGE_SECRET_LENGTH} bytes of Soledad's storage
secret stripped from the first MAC_KEY_LENGTH characters. The HMAC
message is C{doc_id}.
:param doc_id: The id of the document that will be encrypted using
this passphrase.
:type doc_id: str
:return: The passphrase.
:rtype: str
"""
soledad_assert(self.secret is not None)
return hmac.new(
self.secret[MAC_KEY_LENGTH:],
doc_id,
hashlib.sha256).digest()
#
# secret setters/getters
#
def _get_secret(self):
return self._soledad.secrets.remote_storage_secret
secret = property(
_get_secret, doc='The secret used for symmetric encryption')
#
# Crypto utilities for a SoledadDocument.
#
def mac_doc(doc_id, doc_rev, ciphertext, enc_scheme, enc_method, enc_iv,
mac_method, secret):
"""
Calculate a MAC for C{doc} using C{ciphertext}.
Current MAC method used is HMAC, with the following parameters:
* key: sha256(storage_secret, doc_id)
* msg: doc_id + doc_rev + ciphertext
* digestmod: sha256
:param doc_id: The id of the document.
:type doc_id: str
:param doc_rev: The revision of the document.
:type doc_rev: str
:param ciphertext: The content of the document.
:type ciphertext: str
:param enc_scheme: The encryption scheme.
:type enc_scheme: str
:param enc_method: The encryption method.
:type enc_method: str
:param enc_iv: The encryption initialization vector.
:type enc_iv: str
:param mac_method: The MAC method to use.
:type mac_method: str
:param secret: The Soledad storage secret
:type secret: str
:return: The calculated MAC.
:rtype: str
:raise crypto.UnknownMacMethodError: Raised when C{mac_method} is unknown.
"""
try:
soledad_assert(mac_method == crypto.MacMethods.HMAC)
except AssertionError:
raise crypto.UnknownMacMethodError
template = "{doc_id}{doc_rev}{ciphertext}{enc_scheme}{enc_method}{enc_iv}"
content = template.format(
doc_id=doc_id,
doc_rev=doc_rev,
ciphertext=ciphertext,
enc_scheme=enc_scheme,
enc_method=enc_method,
enc_iv=enc_iv)
return hmac.new(
doc_mac_key(doc_id, secret),
content,
hashlib.sha256).digest()
def encrypt_doc(crypto, doc):
"""
Wrapper around encrypt_docstr that accepts a crypto object and the document
as arguments.
:param crypto: a soledad crypto object.
:type crypto: SoledadCrypto
:param doc: the document.
:type doc: SoledadDocument
"""
key = crypto.doc_passphrase(doc.doc_id)
secret = crypto.secret
return encrypt_docstr(
doc.get_json(), doc.doc_id, doc.rev, key, secret)
def encrypt_docstr(docstr, doc_id, doc_rev, key, secret):
"""
Encrypt C{doc}'s content.
Encrypt doc's contents using AES-256 CTR mode and return a valid JSON
string representing the following:
{
crypto.ENC_JSON_KEY: '',
crypto.ENC_SCHEME_KEY: 'symkey',
crypto.ENC_METHOD_KEY: crypto.EncryptionMethods.AES_256_CTR,
crypto.ENC_IV_KEY: '',
MAC_KEY: ''
crypto.MAC_METHOD_KEY: 'hmac'
}
:param docstr: A representation of the document to be encrypted.
:type docstr: str or unicode.
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param key: The key used to encrypt ``data`` (must be 256 bits long).
:type key: str
:param secret: The Soledad storage secret (used for MAC auth).
:type secret: str
:return: The JSON serialization of the dict representing the encrypted
content.
:rtype: str
"""
enc_scheme = crypto.EncryptionSchemes.SYMKEY
enc_method = crypto.EncryptionMethods.AES_256_CTR
mac_method = crypto.MacMethods.HMAC
enc_iv, ciphertext = encrypt_sym(
str(docstr), # encryption/decryption routines expect str
key, method=enc_method)
mac = binascii.b2a_hex( # store the mac as hex.
mac_doc(
doc_id,
doc_rev,
ciphertext,
enc_scheme,
enc_method,
enc_iv,
mac_method,
secret))
# Return a representation for the encrypted content. In the following, we
# convert binary data to hexadecimal representation so the JSON
# serialization does not complain about what it tries to serialize.
hex_ciphertext = binascii.b2a_hex(ciphertext)
return json.dumps({
crypto.ENC_JSON_KEY: hex_ciphertext,
crypto.ENC_SCHEME_KEY: enc_scheme,
crypto.ENC_METHOD_KEY: enc_method,
crypto.ENC_IV_KEY: enc_iv,
crypto.MAC_KEY: mac,
crypto.MAC_METHOD_KEY: mac_method,
})
def decrypt_doc(crypto, doc):
"""
Wrapper around decrypt_doc_dict that accepts a crypto object and the
document as arguments.
:param crypto: a soledad crypto object.
:type crypto: SoledadCrypto
:param doc: the document.
:type doc: SoledadDocument
:return: json string with the decrypted document
:rtype: str
"""
key = crypto.doc_passphrase(doc.doc_id)
secret = crypto.secret
return decrypt_doc_dict(doc.content, doc.doc_id, doc.rev, key, secret)
def _verify_doc_mac(doc_id, doc_rev, ciphertext, enc_scheme, enc_method,
enc_iv, mac_method, secret, doc_mac):
"""
Verify that C{doc_mac} is a correct MAC for the given document.
:param doc_id: The id of the document.
:type doc_id: str
:param doc_rev: The revision of the document.
:type doc_rev: str
:param ciphertext: The content of the document.
:type ciphertext: str
:param enc_scheme: The encryption scheme.
:type enc_scheme: str
:param enc_method: The encryption method.
:type enc_method: str
:param enc_iv: The encryption initialization vector.
:type enc_iv: str
:param mac_method: The MAC method to use.
:type mac_method: str
:param secret: The Soledad storage secret
:type secret: str
:param doc_mac: The MAC to be verified against.
:type doc_mac: str
:raise crypto.UnknownMacMethodError: Raised when C{mac_method} is unknown.
:raise crypto.WrongMacError: Raised when MAC could not be verified.
"""
calculated_mac = mac_doc(
doc_id,
doc_rev,
ciphertext,
enc_scheme,
enc_method,
enc_iv,
mac_method,
secret)
# we compare mac's hashes to avoid possible timing attacks that might
# exploit python's builtin comparison operator behaviour, which fails
# immediatelly when non-matching bytes are found.
doc_mac_hash = hashlib.sha256(
binascii.a2b_hex( # the mac is stored as hex
doc_mac)).digest()
calculated_mac_hash = hashlib.sha256(calculated_mac).digest()
if doc_mac_hash != calculated_mac_hash:
logger.warning("Wrong MAC while decrypting doc...")
raise crypto.WrongMacError("Could not authenticate document's "
"contents.")
def decrypt_doc_dict(doc_dict, doc_id, doc_rev, key, secret):
"""
Decrypt a symmetrically encrypted C{doc}'s content.
Return the JSON string representation of the document's decrypted content.
The passed doc_dict argument should have the following structure:
{
crypto.ENC_JSON_KEY: '',
crypto.ENC_SCHEME_KEY: '',
crypto.ENC_METHOD_KEY: '',
crypto.ENC_IV_KEY: '', # (optional)
MAC_KEY: ''
crypto.MAC_METHOD_KEY: 'hmac'
}
C{enc_blob} is the encryption of the JSON serialization of the document's
content. For now Soledad just deals with documents whose C{enc_scheme} is
crypto.EncryptionSchemes.SYMKEY and C{enc_method} is
crypto.EncryptionMethods.AES_256_CTR.
:param doc_dict: The content of the document to be decrypted.
:type doc_dict: dict
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param key: The key used to encrypt ``data`` (must be 256 bits long).
:type key: str
:param secret:
:type secret:
:return: The JSON serialization of the decrypted content.
:rtype: str
:raise UnknownEncryptionMethodError: Raised when trying to decrypt from an
unknown encryption method.
"""
# assert document dictionary structure
expected_keys = set([
crypto.ENC_JSON_KEY,
crypto.ENC_SCHEME_KEY,
crypto.ENC_METHOD_KEY,
crypto.ENC_IV_KEY,
crypto.MAC_KEY,
crypto.MAC_METHOD_KEY,
])
soledad_assert(expected_keys.issubset(set(doc_dict.keys())))
ciphertext = binascii.a2b_hex(doc_dict[crypto.ENC_JSON_KEY])
enc_scheme = doc_dict[crypto.ENC_SCHEME_KEY]
enc_method = doc_dict[crypto.ENC_METHOD_KEY]
enc_iv = doc_dict[crypto.ENC_IV_KEY]
doc_mac = doc_dict[crypto.MAC_KEY]
mac_method = doc_dict[crypto.MAC_METHOD_KEY]
soledad_assert(enc_scheme == crypto.EncryptionSchemes.SYMKEY)
_verify_doc_mac(
doc_id, doc_rev, ciphertext, enc_scheme, enc_method,
enc_iv, mac_method, secret, doc_mac)
return decrypt_sym(ciphertext, key, method=enc_method, iv=enc_iv)
def is_symmetrically_encrypted(doc):
"""
Return True if the document was symmetrically encrypted.
:param doc: The document to check.
:type doc: SoledadDocument
:rtype: bool
"""
if doc.content and crypto.ENC_SCHEME_KEY in doc.content:
if doc.content[crypto.ENC_SCHEME_KEY] \
== crypto.EncryptionSchemes.SYMKEY:
return True
return False
#
# Encrypt/decrypt pools of workers
#
class SyncEncryptDecryptPool(object):
"""
Base class for encrypter/decrypter pools.
"""
WORKERS = multiprocessing.cpu_count()
def __init__(self, crypto, sync_db, write_lock):
"""
Initialize the pool of encryption-workers.
:param crypto: A SoledadCryto instance to perform the encryption.
:type crypto: leap.soledad.crypto.SoledadCrypto
:param sync_db: A database connection handle
:type sync_db: pysqlcipher.dbapi2.Connection
:param write_lock: a write lock for controlling concurrent access
to the sync_db
:type write_lock: threading.Lock
"""
self._pool = multiprocessing.Pool(self.WORKERS)
self._crypto = crypto
self._sync_db = sync_db
self._sync_db_write_lock = write_lock
def close(self):
"""
Cleanly close the pool of workers.
"""
logger.debug("Closing %s" % (self.__class__.__name__,))
self._pool.close()
try:
self._pool.join()
except Exception:
pass
def terminate(self):
"""
Terminate the pool of workers.
"""
logger.debug("Terminating %s" % (self.__class__.__name__,))
self._pool.terminate()
def encrypt_doc_task(doc_id, doc_rev, content, key, secret):
"""
Encrypt the content of the given document.
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param content: The serialized content of the document.
:type content: str
:param key: The encryption key.
:type key: str
:param secret: The Soledad storage secret (used for MAC auth).
:type secret: str
:return: A tuple containing the doc id, revision and encrypted content.
:rtype: tuple(str, str, str)
"""
encrypted_content = encrypt_docstr(
content, doc_id, doc_rev, key, secret)
return doc_id, doc_rev, encrypted_content
class SyncEncrypterPool(SyncEncryptDecryptPool):
"""
Pool of workers that spawn subprocesses to execute the symmetric encryption
of documents to be synced.
"""
# TODO implement throttling to reduce cpu usage??
WORKERS = multiprocessing.cpu_count()
TABLE_NAME = "docs_tosync"
FIELD_NAMES = "doc_id, rev, content"
def encrypt_doc(self, doc, workers=True):
"""
Symmetrically encrypt a document.
:param doc: The document with contents to be encrypted.
:type doc: SoledadDocument
:param workers: Whether to defer the decryption to the multiprocess
pool of workers. Useful for debugging purposes.
:type workers: bool
"""
soledad_assert(self._crypto is not None, "need a crypto object")
docstr = doc.get_json()
key = self._crypto.doc_passphrase(doc.doc_id)
secret = self._crypto.secret
args = doc.doc_id, doc.rev, docstr, key, secret
try:
if workers:
res = self._pool.apply_async(
encrypt_doc_task, args,
callback=self.encrypt_doc_cb)
else:
# encrypt inline
res = encrypt_doc_task(*args)
self.encrypt_doc_cb(res)
except Exception as exc:
logger.exception(exc)
def encrypt_doc_cb(self, result):
"""
Insert results of encryption routine into the local sync database.
:param result: A tuple containing the doc id, revision and encrypted
content.
:type result: tuple(str, str, str)
"""
doc_id, doc_rev, content = result
self.insert_encrypted_local_doc(doc_id, doc_rev, content)
def insert_encrypted_local_doc(self, doc_id, doc_rev, content):
"""
Insert the contents of the encrypted doc into the local sync
database.
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param content: The serialized content of the document.
:type content: str
:param content: The encrypted document.
:type content: str
"""
# FIXME --- callback should complete immediately since otherwise the
# thread which handles the results will get blocked
# Right now we're blocking the dispatcher with the writes to sqlite.
sql_del = "DELETE FROM '%s' WHERE doc_id=?" % (self.TABLE_NAME,)
sql_ins = "INSERT INTO '%s' VALUES (?, ?, ?)" % (self.TABLE_NAME,)
con = self._sync_db
with self._sync_db_write_lock:
con.execute(sql_del, (doc_id, ))
con.execute(sql_ins, (doc_id, doc_rev, content))
def decrypt_doc_task(doc_id, doc_rev, content, gen, trans_id, key, secret):
"""
Decrypt the content of the given document.
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param content: The encrypted content of the document.
:type content: str
:param gen: The generation corresponding to the modification of that
document.
:type gen: int
:param trans_id: The transaction id corresponding to the modification of
that document.
:type trans_id: str
:param key: The encryption key.
:type key: str
:param secret: The Soledad storage secret (used for MAC auth).
:type secret: str
:return: A tuple containing the doc id, revision and encrypted content.
:rtype: tuple(str, str, str)
"""
decrypted_content = decrypt_doc_dict(
content, doc_id, doc_rev, key, secret)
return doc_id, doc_rev, decrypted_content, gen, trans_id
class SyncDecrypterPool(SyncEncryptDecryptPool):
"""
Pool of workers that spawn subprocesses to execute the symmetric decryption
of documents that were received.
The decryption of the received documents is done in two steps:
1. All the encrypted docs are collected, together with their generation
and transaction-id
2. The docs are enqueued for decryption. When completed, they are
inserted following the generation order.
"""
# TODO implement throttling to reduce cpu usage??
TABLE_NAME = "docs_received"
FIELD_NAMES = "doc_id, rev, content, gen, trans_id, encrypted"
write_encrypted_lock = threading.Lock()
def __init__(self, *args, **kwargs):
"""
Initialize the decrypter pool, and setup a dict for putting the
results of the decrypted docs until they are picked by the insert
routine that gets them in order.
:param insert_doc_cb: A callback for inserting received documents from
target. If not overriden, this will call u1db
insert_doc_from_target in synchronizer, which
implements the TAKE OTHER semantics.
:type insert_doc_cb: function
:param last_known_generation: Target's last known generation.
:type last_known_generation: int
"""
self._insert_doc_cb = kwargs.pop("insert_doc_cb")
SyncEncryptDecryptPool.__init__(self, *args, **kwargs)
self.source_replica_uid = None
self._async_results = []
def set_source_replica_uid(self, source_replica_uid):
"""
Set the source replica uid for this decrypter pool instance.
:param source_replica_uid: The uid of the source replica.
:type source_replica_uid: str
"""
self.source_replica_uid = source_replica_uid
def insert_encrypted_received_doc(self, doc_id, doc_rev, content,
gen, trans_id):
"""
Insert a received message with encrypted content, to be decrypted later
on.
:param doc_id: The Document ID.
:type doc_id: str
:param doc_rev: The Document Revision
:param doc_rev: str
:param content: the Content of the document
:type content: str
:param gen: the Document Generation
:type gen: int
:param trans_id: Transaction ID
:type trans_id: str
"""
docstr = json.dumps(content)
sql_del = "DELETE FROM '%s' WHERE doc_id=?" % (self.TABLE_NAME,)
sql_ins = "INSERT INTO '%s' VALUES (?, ?, ?, ?, ?, ?)" % (
self.TABLE_NAME,)
con = self._sync_db
with self._sync_db_write_lock:
con.execute(sql_del, (doc_id, ))
con.execute(
sql_ins,
(doc_id, doc_rev, docstr, gen, trans_id, 1))
def insert_received_doc(self, doc_id, doc_rev, content, gen, trans_id):
"""
Insert a document that is not symmetrically encrypted.
We store it in the staging area (the decrypted_docs dictionary) to be
picked up in order as the preceding documents are decrypted.
:param doc_id: The Document ID.
:type doc_id: str
:param doc_rev: The Document Revision
:param doc_rev: str
:param content: the Content of the document
:type content: str
:param gen: the Document Generation
:type gen: int
:param trans_id: Transaction ID
:type trans_id: str
"""
if not isinstance(content, str):
content = json.dumps(content)
sql_del = "DELETE FROM '%s' WHERE doc_id=?" % (
self.TABLE_NAME,)
sql_ins = "INSERT INTO '%s' VALUES (?, ?, ?, ?, ?, ?)" % (
self.TABLE_NAME,)
con = self._sync_db
with self._sync_db_write_lock:
con.execute(sql_del, (doc_id,))
con.execute(
sql_ins,
(doc_id, doc_rev, content, gen, trans_id, 0))
def delete_received_doc(self, doc_id, doc_rev):
"""
Delete a received doc after it was inserted into the local db.
:param doc_id: Document ID.
:type doc_id: str
:param doc_rev: Document revision.
:type doc_rev: str
"""
sql_del = "DELETE FROM '%s' WHERE doc_id=? AND rev=?" % (
self.TABLE_NAME,)
con = self._sync_db
with self._sync_db_write_lock:
con.execute(sql_del, (doc_id, doc_rev))
def decrypt_doc(self, doc_id, rev, content, gen, trans_id,
source_replica_uid, workers=True):
"""
Symmetrically decrypt a document.
:param doc_id: The ID for the document with contents to be encrypted.
:type doc: str
:param rev: The revision of the document.
:type rev: str
:param content: The serialized content of the document.
:type content: str
:param gen: The generation corresponding to the modification of that
document.
:type gen: int
:param trans_id: The transaction id corresponding to the modification
of that document.
:type trans_id: str
:param source_replica_uid:
:type source_replica_uid: str
:param workers: Whether to defer the decryption to the multiprocess
pool of workers. Useful for debugging purposes.
:type workers: bool
"""
self.source_replica_uid = source_replica_uid
# insert_doc_cb is a proxy object that gets updated with the right
# insert function only when the sync_target invokes the sync_exchange
# method. so, if we don't still have a non-empty callback, we refuse
# to proceed.
if sameProxiedObjects(self._insert_doc_cb.get(source_replica_uid),
None):
logger.debug("Sync decrypter pool: no insert_doc_cb() yet.")
return
soledad_assert(self._crypto is not None, "need a crypto object")
if len(content) == 0:
# not encrypted payload
return
content = json.loads(content)
key = self._crypto.doc_passphrase(doc_id)
secret = self._crypto.secret
args = doc_id, rev, content, gen, trans_id, key, secret
if workers:
# save the async result object so we can inspect it for failures
self._async_results.append(self._pool.apply_async(
decrypt_doc_task, args,
callback=self.decrypt_doc_cb))
else:
# decrypt inline
res = decrypt_doc_task(*args)
self.decrypt_doc_cb(res)
def decrypt_doc_cb(self, result):
"""
Store the decryption result in the sync db from where it will later be
picked by process_decrypted.
:param result: A tuple containing the doc id, revision and encrypted
content.
:type result: tuple(str, str, str)
"""
doc_id, rev, content, gen, trans_id = result
logger.debug("Sync decrypter pool: decrypted doc %s: %s %s %s"
% (doc_id, rev, gen, trans_id))
self.insert_received_doc(doc_id, rev, content, gen, trans_id)
def get_docs_by_generation(self, encrypted=None):
"""
Get all documents in the received table from the sync db,
ordered by generation.
:param encrypted: If not None, only return documents with encrypted
field equal to given parameter.
:type encrypted: bool or None
:return: list of doc_id, rev, generation, gen, trans_id
:rtype: list
"""
sql = "SELECT doc_id, rev, content, gen, trans_id, encrypted FROM %s" \
% self.TABLE_NAME
if encrypted is not None:
sql += " WHERE encrypted = %d" % int(encrypted)
sql += " ORDER BY gen ASC"
return self._fetchall(sql)
def get_insertable_docs_by_gen(self):
"""
Return a list of non-encrypted documents ready to be inserted.
"""
# here, we compare the list of all available docs with the list of
# decrypted docs and find the longest common prefix between these two
# lists. Note that the order of lists fetch matters: if instead we
# first fetch the list of decrypted docs and then the list of all
# docs, then some document might have been decrypted between these two
# calls, and if it is just the right doc then it might not be caught
# by the next loop.
all_docs = self.get_docs_by_generation()
decrypted_docs = self.get_docs_by_generation(encrypted=False)
insertable = []
for doc_id, rev, _, gen, trans_id, encrypted in all_docs:
for next_doc_id, _, next_content, _, _, _ in decrypted_docs:
if doc_id == next_doc_id:
content = next_content
insertable.append((doc_id, rev, content, gen, trans_id))
else:
break
return insertable
def count_docs_in_sync_db(self, encrypted=None):
"""
Count how many documents we have in the table for received docs.
:param encrypted: If not None, return count of documents with
encrypted field equal to given parameter.
:type encrypted: bool or None
:return: The count of documents.
:rtype: int
"""
if self._sync_db is None:
logger.warning("cannot return count with null sync_db")
return
sql = "SELECT COUNT(*) FROM %s" % (self.TABLE_NAME,)
if encrypted is not None:
sql += " WHERE encrypted = %d" % int(encrypted)
res = self._fetchall(sql)
if res:
val = res.pop()
return val[0]
else:
return 0
def decrypt_received_docs(self):
"""
Get all the encrypted documents from the sync database and dispatch a
decrypt worker to decrypt each one of them.
"""
docs_by_generation = self.get_docs_by_generation(encrypted=True)
for doc_id, rev, content, gen, trans_id, _ \
in filter(None, docs_by_generation):
self.decrypt_doc(
doc_id, rev, content, gen, trans_id, self.source_replica_uid)
def process_decrypted(self):
"""
Process the already decrypted documents, and insert as many documents
as can be taken from the expected order without finding a gap.
:return: Whether we have processed all the pending docs.
:rtype: bool
"""
# Acquire the lock to avoid processing while we're still
# getting data from the syncing stream, to avoid InvalidGeneration
# problems.
with self.write_encrypted_lock:
for doc_fields in self.get_insertable_docs_by_gen():
self.insert_decrypted_local_doc(*doc_fields)
remaining = self.count_docs_in_sync_db()
return remaining == 0
def insert_decrypted_local_doc(self, doc_id, doc_rev, content,
gen, trans_id):
"""
Insert the decrypted document into the local sqlcipher database.
Makes use of the passed callback `return_doc_cb` passed to the caller
by u1db sync.
:param doc_id: The document id.
:type doc_id: str
:param doc_rev: The document revision.
:type doc_rev: str
:param content: The serialized content of the document.
:type content: str
:param gen: The generation corresponding to the modification of that
document.
:type gen: int
:param trans_id: The transaction id corresponding to the modification
of that document.
:type trans_id: str
"""
# could pass source_replica in params for callback chain
insert_fun = self._insert_doc_cb[self.source_replica_uid]
logger.debug("Sync decrypter pool: inserting doc in local db: "
"%s:%s %s" % (doc_id, doc_rev, gen))
# convert deleted documents to avoid error on document creation
if content == 'null':
content = None
doc = SoledadDocument(doc_id, doc_rev, content)
gen = int(gen)
insert_fun(doc, gen, trans_id)
# If no errors found, remove it from the received database.
self.delete_received_doc(doc_id, doc_rev)
def empty(self):
"""
Empty the received docs table of the sync database.
"""
sql = "DELETE FROM %s WHERE 1" % (self.TABLE_NAME,)
self._sync_db.execute(sql)
def _fetchall(self, *args, **kwargs):
with self._sync_db:
c = self._sync_db.cursor()
c.execute(*args, **kwargs)
return c.fetchall()
def raise_in_case_of_failed_async_calls(self):
"""
Re-raise any exception raised by an async call.
:raise Exception: Raised if an async call has raised an exception.
"""
for res in self._async_results:
if res.ready():
if not res.successful():
# re-raise the exception raised by the remote call
res.get()