import binascii import time now = time.time from zope.interface import implements from twisted.internet import defer from allmydata import uri from twisted.internet.interfaces import IConsumer from allmydata.interfaces import IImmutableFileNode, IUploadResults from allmydata.util import consumer from allmydata.check_results import CheckResults, CheckAndRepairResults from allmydata.util.dictutil import DictOfSets from pycryptopp.cipher.aes import AES # local imports from allmydata.immutable.checker import Checker from allmydata.immutable.repairer import Repairer from allmydata.immutable.downloader.node import DownloadNode, \ IDownloadStatusHandlingConsumer from allmydata.immutable.downloader.status import DownloadStatus class CiphertextFileNode: def __init__(self, verifycap, storage_broker, secret_holder, terminator, history): assert isinstance(verifycap, uri.CHKFileVerifierURI) self._verifycap = verifycap self._storage_broker = storage_broker self._secret_holder = secret_holder self._terminator = terminator self._history = history self._download_status = None self._node = None # created lazily, on read() def _maybe_create_download_node(self): if not self._download_status: ds = DownloadStatus(self._verifycap.storage_index, self._verifycap.size) if self._history: self._history.add_download(ds) self._download_status = ds if self._node is None: self._node = DownloadNode(self._verifycap, self._storage_broker, self._secret_holder, self._terminator, self._history, self._download_status) def read(self, consumer, offset=0, size=None): """I am the main entry point, from which FileNode.read() can get data. I feed the consumer with the desired range of ciphertext. I return a Deferred that fires (with the consumer) when the read is finished.""" self._maybe_create_download_node() return self._node.read(consumer, offset, size) def get_segment(self, segnum): """Begin downloading a segment. I return a tuple (d, c): 'd' is a Deferred that fires with (offset,data) when the desired segment is available, and c is an object on which c.cancel() can be called to disavow interest in the segment (after which 'd' will never fire). You probably need to know the segment size before calling this, unless you want the first few bytes of the file. If you ask for a segment number which turns out to be too large, the Deferred will errback with BadSegmentNumberError. The Deferred fires with the offset of the first byte of the data segment, so that you can call get_segment() before knowing the segment size, and still know which data you received. """ self._maybe_create_download_node() return self._node.get_segment(segnum) def get_segment_size(self): # return a Deferred that fires with the file's real segment size self._maybe_create_download_node() return self._node.get_segsize() def get_storage_index(self): return self._verifycap.storage_index def get_verify_cap(self): return self._verifycap def get_size(self): return self._verifycap.size def raise_error(self): pass def check_and_repair(self, monitor, verify=False, add_lease=False): c = Checker(verifycap=self._verifycap, servers=self._storage_broker.get_connected_servers(), verify=verify, add_lease=add_lease, secret_holder=self._secret_holder, monitor=monitor) d = c.start() d.addCallback(self._maybe_repair, monitor) return d def _maybe_repair(self, cr, monitor): crr = CheckAndRepairResults(self._verifycap.storage_index) crr.pre_repair_results = cr if cr.is_healthy(): crr.post_repair_results = cr return defer.succeed(crr) crr.repair_attempted = True crr.repair_successful = False # until proven successful def _repair_error(f): # as with mutable repair, I'm not sure if I want to pass # through a failure or not. TODO crr.repair_successful = False crr.repair_failure = f return f r = Repairer(self, storage_broker=self._storage_broker, secret_holder=self._secret_holder, monitor=monitor) d = r.start() d.addCallbacks(self._gather_repair_results, _repair_error, callbackArgs=(cr, crr,)) return d def _gather_repair_results(self, ur, cr, crr): assert IUploadResults.providedBy(ur), ur # clone the cr (check results) to form the basis of the # prr (post-repair results) verifycap = self._verifycap servers_responding = set(cr.get_servers_responding()) sm = DictOfSets() assert isinstance(cr.get_sharemap(), DictOfSets) for shnum, servers in cr.get_sharemap().items(): for server in servers: sm.add(shnum, server) for shnum, servers in ur.get_sharemap().items(): for server in servers: sm.add(shnum, server) servers_responding.add(server) servers_responding = sorted(servers_responding) good_hosts = len(reduce(set.union, sm.values(), set())) is_healthy = bool(len(sm) >= verifycap.total_shares) is_recoverable = bool(len(sm) >= verifycap.needed_shares) needs_rebalancing = bool(len(sm) >= verifycap.total_shares) prr = CheckResults(cr.get_uri(), cr.get_storage_index(), healthy=is_healthy, recoverable=is_recoverable, needs_rebalancing=needs_rebalancing, count_shares_needed=verifycap.needed_shares, count_shares_expected=verifycap.total_shares, count_shares_good=len(sm), count_good_share_hosts=good_hosts, count_recoverable_versions=int(is_recoverable), count_unrecoverable_versions=int(not is_recoverable), servers_responding=list(servers_responding), sharemap=sm, count_wrong_shares=0, # no such thing as wrong, for immutable list_corrupt_shares=cr.get_new_corrupt_shares(), count_corrupt_shares=len(cr.get_corrupt_shares()), list_incompatible_shares=cr.get_new_incompatible_shares(), count_incompatible_shares=len(cr.get_incompatible_shares()), summary="", report=[], share_problems=[], servermap=None) crr.repair_successful = is_healthy crr.post_repair_results = prr return crr def check(self, monitor, verify=False, add_lease=False): verifycap = self._verifycap sb = self._storage_broker servers = sb.get_connected_servers() sh = self._secret_holder v = Checker(verifycap=verifycap, servers=servers, verify=verify, add_lease=add_lease, secret_holder=sh, monitor=monitor) return v.start() class DecryptingConsumer: """I sit between a CiphertextDownloader (which acts as a Producer) and the real Consumer, decrypting everything that passes by. The real Consumer sees the real Producer, but the Producer sees us instead of the real consumer.""" implements(IConsumer, IDownloadStatusHandlingConsumer) def __init__(self, consumer, readkey, offset): self._consumer = consumer self._read_ev = None self._download_status = None # TODO: pycryptopp CTR-mode needs random-access operations: I want # either a=AES(readkey, offset) or better yet both of: # a=AES(readkey, offset=0) # a.process(ciphertext, offset=xyz) # For now, we fake it with the existing iv= argument. offset_big = offset // 16 offset_small = offset % 16 iv = binascii.unhexlify("%032x" % offset_big) self._decryptor = AES(readkey, iv=iv) self._decryptor.process("\x00"*offset_small) def set_download_status_read_event(self, read_ev): self._read_ev = read_ev def set_download_status(self, ds): self._download_status = ds def registerProducer(self, producer, streaming): # this passes through, so the real consumer can flow-control the real # producer. Therefore we don't need to provide any IPushProducer # methods. We implement all the IConsumer methods as pass-throughs, # and only intercept write() to perform decryption. self._consumer.registerProducer(producer, streaming) def unregisterProducer(self): self._consumer.unregisterProducer() def write(self, ciphertext): started = now() plaintext = self._decryptor.process(ciphertext) if self._read_ev: elapsed = now() - started self._read_ev.update(0, elapsed, 0) if self._download_status: self._download_status.add_misc_event("AES", started, now()) self._consumer.write(plaintext) class ImmutableFileNode: implements(IImmutableFileNode) # I wrap a CiphertextFileNode with a decryption key def __init__(self, filecap, storage_broker, secret_holder, terminator, history): assert isinstance(filecap, uri.CHKFileURI) verifycap = filecap.get_verify_cap() self._cnode = CiphertextFileNode(verifycap, storage_broker, secret_holder, terminator, history) assert isinstance(filecap, uri.CHKFileURI) self.u = filecap self._readkey = filecap.key # TODO: I'm not sure about this.. what's the use case for node==node? If # we keep it here, we should also put this on CiphertextFileNode def __hash__(self): return self.u.__hash__() def __eq__(self, other): if isinstance(other, ImmutableFileNode): return self.u.__eq__(other.u) else: return False def __ne__(self, other): if isinstance(other, ImmutableFileNode): return self.u.__eq__(other.u) else: return True def read(self, consumer, offset=0, size=None): decryptor = DecryptingConsumer(consumer, self._readkey, offset) d = self._cnode.read(decryptor, offset, size) d.addCallback(lambda dc: consumer) return d def raise_error(self): pass def get_write_uri(self): return None def get_readonly_uri(self): return self.get_uri() def get_uri(self): return self.u.to_string() def get_cap(self): return self.u def get_readcap(self): return self.u.get_readonly() def get_verify_cap(self): return self.u.get_verify_cap() def get_repair_cap(self): # CHK files can be repaired with just the verifycap return self.u.get_verify_cap() def get_storage_index(self): return self.u.get_storage_index() def get_size(self): return self.u.get_size() def get_current_size(self): return defer.succeed(self.get_size()) def is_mutable(self): return False def is_readonly(self): return True def is_unknown(self): return False def is_allowed_in_immutable_directory(self): return True def check_and_repair(self, monitor, verify=False, add_lease=False): return self._cnode.check_and_repair(monitor, verify, add_lease) def check(self, monitor, verify=False, add_lease=False): return self._cnode.check(monitor, verify, add_lease) def get_best_readable_version(self): """ Return an IReadable of the best version of this file. Since immutable files can have only one version, we just return the current filenode. """ return defer.succeed(self) def download_best_version(self): """ Download the best version of this file, returning its contents as a bytestring. Since there is only one version of an immutable file, we download and return the contents of this file. """ d = consumer.download_to_data(self) return d # for an immutable file, download_to_data (specified in IReadable) # is the same as download_best_version (specified in IFileNode). For # mutable files, the difference is more meaningful, since they can # have multiple versions. download_to_data = download_best_version # get_size() (IReadable), get_current_size() (IFilesystemNode), and # get_size_of_best_version(IFileNode) are all the same for immutable # files. get_size_of_best_version = get_current_size