From: Kevan Carstensen Date: Tue, 2 Aug 2011 01:39:31 +0000 (-0700) Subject: mutable/publish: teach the publisher how to publish MDMF mutable files X-Git-Tag: trac-5200~32 X-Git-Url: https://git.rkrishnan.org/components/com_hotproperty/css/htmlfontify-example.html?a=commitdiff_plain;h=1576c35d387531930424a2c1a9b179b65c493de2;p=tahoe-lafs%2Ftahoe-lafs.git mutable/publish: teach the publisher how to publish MDMF mutable files Like the downloader, the publisher needs some substantial changes to handle multiple segment mutable files. --- diff --git a/src/allmydata/mutable/publish.py b/src/allmydata/mutable/publish.py index 580682b6..066ee904 100644 --- a/src/allmydata/mutable/publish.py +++ b/src/allmydata/mutable/publish.py @@ -1,11 +1,13 @@ -import os, struct, time +import os, time +from StringIO import StringIO from itertools import count from zope.interface import implements from twisted.internet import defer from twisted.python import failure -from allmydata.interfaces import IPublishStatus +from allmydata.interfaces import IPublishStatus, SDMF_VERSION, MDMF_VERSION, \ + IMutableUploadable from allmydata.util import base32, hashutil, mathutil, idlib, log from allmydata.util.dictutil import DictOfSets from allmydata import hashtree, codec @@ -16,8 +18,14 @@ from foolscap.api import eventually, fireEventually from allmydata.mutable.common import MODE_WRITE, MODE_CHECK, \ UncoordinatedWriteError, NotEnoughServersError from allmydata.mutable.servermap import ServerMap -from allmydata.mutable.layout import pack_prefix, pack_share, unpack_header, pack_checkstring, \ - unpack_checkstring, SIGNED_PREFIX +from allmydata.mutable.layout import unpack_checkstring, MDMFSlotWriteProxy, \ + SDMFSlotWriteProxy + +KiB = 1024 +DEFAULT_MAX_SEGMENT_SIZE = 128 * KiB +PUSHING_BLOCKS_STATE = 0 +PUSHING_EVERYTHING_ELSE_STATE = 1 +DONE_STATE = 2 class PublishStatus: implements(IPublishStatus) @@ -101,12 +109,16 @@ class Publish: self._log_number = num self._running = True self._first_write_error = None + self._last_failure = None self._status = PublishStatus() self._status.set_storage_index(self._storage_index) self._status.set_helper(False) self._status.set_progress(0.0) self._status.set_active(True) + self._version = self._node.get_version() + assert self._version in (SDMF_VERSION, MDMF_VERSION) + def get_status(self): return self._status @@ -118,6 +130,212 @@ class Publish: kwargs["facility"] = "tahoe.mutable.publish" return log.msg(*args, **kwargs) + + def update(self, data, offset, blockhashes, version): + """ + I replace the contents of this file with the contents of data, + starting at offset. I return a Deferred that fires with None + when the replacement has been completed, or with an error if + something went wrong during the process. + + Note that this process will not upload new shares. If the file + being updated is in need of repair, callers will have to repair + it on their own. + """ + # How this works: + # 1: Make peer assignments. We'll assign each share that we know + # about on the grid to that peer that currently holds that + # share, and will not place any new shares. + # 2: Setup encoding parameters. Most of these will stay the same + # -- datalength will change, as will some of the offsets. + # 3. Upload the new segments. + # 4. Be done. + assert IMutableUploadable.providedBy(data) + + self.data = data + + # XXX: Use the MutableFileVersion instead. + self.datalength = self._node.get_size() + if data.get_size() > self.datalength: + self.datalength = data.get_size() + + self.log("starting update") + self.log("adding new data of length %d at offset %d" % \ + (data.get_size(), offset)) + self.log("new data length is %d" % self.datalength) + self._status.set_size(self.datalength) + self._status.set_status("Started") + self._started = time.time() + + self.done_deferred = defer.Deferred() + + self._writekey = self._node.get_writekey() + assert self._writekey, "need write capability to publish" + + # first, which servers will we publish to? We require that the + # servermap was updated in MODE_WRITE, so we can depend upon the + # peerlist computed by that process instead of computing our own. + assert self._servermap + assert self._servermap.last_update_mode in (MODE_WRITE, MODE_CHECK) + # we will push a version that is one larger than anything present + # in the grid, according to the servermap. + self._new_seqnum = self._servermap.highest_seqnum() + 1 + self._status.set_servermap(self._servermap) + + self.log(format="new seqnum will be %(seqnum)d", + seqnum=self._new_seqnum, level=log.NOISY) + + # We're updating an existing file, so all of the following + # should be available. + self.readkey = self._node.get_readkey() + self.required_shares = self._node.get_required_shares() + assert self.required_shares is not None + self.total_shares = self._node.get_total_shares() + assert self.total_shares is not None + self._status.set_encoding(self.required_shares, self.total_shares) + + self._pubkey = self._node.get_pubkey() + assert self._pubkey + self._privkey = self._node.get_privkey() + assert self._privkey + self._encprivkey = self._node.get_encprivkey() + + sb = self._storage_broker + full_peerlist = [(s.get_serverid(), s.get_rref()) + for s in sb.get_servers_for_psi(self._storage_index)] + self.full_peerlist = full_peerlist # for use later, immutable + self.bad_peers = set() # peerids who have errbacked/refused requests + + # This will set self.segment_size, self.num_segments, and + # self.fec. TODO: Does it know how to do the offset? Probably + # not. So do that part next. + self.setup_encoding_parameters(offset=offset) + + # if we experience any surprises (writes which were rejected because + # our test vector did not match, or shares which we didn't expect to + # see), we set this flag and report an UncoordinatedWriteError at the + # end of the publish process. + self.surprised = False + + # we keep track of three tables. The first is our goal: which share + # we want to see on which servers. This is initially populated by the + # existing servermap. + self.goal = set() # pairs of (peerid, shnum) tuples + + # the second table is our list of outstanding queries: those which + # are in flight and may or may not be delivered, accepted, or + # acknowledged. Items are added to this table when the request is + # sent, and removed when the response returns (or errbacks). + self.outstanding = set() # (peerid, shnum) tuples + + # the third is a table of successes: share which have actually been + # placed. These are populated when responses come back with success. + # When self.placed == self.goal, we're done. + self.placed = set() # (peerid, shnum) tuples + + # we also keep a mapping from peerid to RemoteReference. Each time we + # pull a connection out of the full peerlist, we add it to this for + # use later. + self.connections = {} + + self.bad_share_checkstrings = {} + + # This is set at the last step of the publishing process. + self.versioninfo = "" + + # we use the servermap to populate the initial goal: this way we will + # try to update each existing share in place. Since we're + # updating, we ignore damaged and missing shares -- callers must + # do a repair to repair and recreate these. + for (peerid, shnum) in self._servermap.servermap: + self.goal.add( (peerid, shnum) ) + self.connections[peerid] = self._servermap.connections[peerid] + self.writers = {} + + # SDMF files are updated differently. + self._version = MDMF_VERSION + writer_class = MDMFSlotWriteProxy + + # For each (peerid, shnum) in self.goal, we make a + # write proxy for that peer. We'll use this to write + # shares to the peer. + for key in self.goal: + peerid, shnum = key + write_enabler = self._node.get_write_enabler(peerid) + renew_secret = self._node.get_renewal_secret(peerid) + cancel_secret = self._node.get_cancel_secret(peerid) + secrets = (write_enabler, renew_secret, cancel_secret) + + self.writers[shnum] = writer_class(shnum, + self.connections[peerid], + self._storage_index, + secrets, + self._new_seqnum, + self.required_shares, + self.total_shares, + self.segment_size, + self.datalength) + self.writers[shnum].peerid = peerid + assert (peerid, shnum) in self._servermap.servermap + old_versionid, old_timestamp = self._servermap.servermap[key] + (old_seqnum, old_root_hash, old_salt, old_segsize, + old_datalength, old_k, old_N, old_prefix, + old_offsets_tuple) = old_versionid + self.writers[shnum].set_checkstring(old_seqnum, + old_root_hash, + old_salt) + + # Our remote shares will not have a complete checkstring until + # after we are done writing share data and have started to write + # blocks. In the meantime, we need to know what to look for when + # writing, so that we can detect UncoordinatedWriteErrors. + self._checkstring = self.writers.values()[0].get_checkstring() + + # Now, we start pushing shares. + self._status.timings["setup"] = time.time() - self._started + # First, we encrypt, encode, and publish the shares that we need + # to encrypt, encode, and publish. + + # Our update process fetched these for us. We need to update + # them in place as publishing happens. + self.blockhashes = {} # (shnum, [blochashes]) + for (i, bht) in blockhashes.iteritems(): + # We need to extract the leaves from our old hash tree. + old_segcount = mathutil.div_ceil(version[4], + version[3]) + h = hashtree.IncompleteHashTree(old_segcount) + bht = dict(enumerate(bht)) + h.set_hashes(bht) + leaves = h[h.get_leaf_index(0):] + for j in xrange(self.num_segments - len(leaves)): + leaves.append(None) + + assert len(leaves) >= self.num_segments + self.blockhashes[i] = leaves + # This list will now be the leaves that were set during the + # initial upload + enough empty hashes to make it a + # power-of-two. If we exceed a power of two boundary, we + # should be encoding the file over again, and should not be + # here. So, we have + #assert len(self.blockhashes[i]) == \ + # hashtree.roundup_pow2(self.num_segments), \ + # len(self.blockhashes[i]) + # XXX: Except this doesn't work. Figure out why. + + # These are filled in later, after we've modified the block hash + # tree suitably. + self.sharehash_leaves = None # eventually [sharehashes] + self.sharehashes = {} # shnum -> [sharehash leaves necessary to + # validate the share] + + self.log("Starting push") + + self._state = PUSHING_BLOCKS_STATE + self._push() + + return self.done_deferred + + def publish(self, newdata): """Publish the filenode's current contents. Returns a Deferred that fires (with None) when the publish has done as much work as it's ever @@ -125,17 +343,19 @@ class Publish: simultaneous write. """ - # 1: generate shares (SDMF: files are small, so we can do it in RAM) - # 2: perform peer selection, get candidate servers - # 2a: send queries to n+epsilon servers, to determine current shares - # 2b: based upon responses, create target map - # 3: send slot_testv_and_readv_and_writev messages - # 4: as responses return, update share-dispatch table - # 4a: may need to run recovery algorithm - # 5: when enough responses are back, we're done - - self.log("starting publish, datalen is %s" % len(newdata)) - self._status.set_size(len(newdata)) + # 0. Setup encoding parameters, encoder, and other such things. + # 1. Encrypt, encode, and publish segments. + assert IMutableUploadable.providedBy(newdata) + + self.data = newdata + self.datalength = newdata.get_size() + #if self.datalength >= DEFAULT_MAX_SEGMENT_SIZE: + # self._version = MDMF_VERSION + #else: + # self._version = SDMF_VERSION + + self.log("starting publish, datalen is %s" % self.datalength) + self._status.set_size(self.datalength) self._status.set_status("Started") self._started = time.time() @@ -184,9 +404,8 @@ class Publish: self.full_peerlist = full_peerlist # for use later, immutable self.bad_peers = set() # peerids who have errbacked/refused requests - self.newdata = newdata - self.salt = os.urandom(16) - + # This will set self.segment_size, self.num_segments, and + # self.fec. self.setup_encoding_parameters() # if we experience any surprises (writes which were rejected because @@ -195,10 +414,6 @@ class Publish: # end of the publish process. self.surprised = False - # as a failsafe, refuse to iterate through self.loop more than a - # thousand times. - self.looplimit = 1000 - # we keep track of three tables. The first is our goal: which share # we want to see on which servers. This is initially populated by the # existing servermap. @@ -222,6 +437,9 @@ class Publish: self.bad_share_checkstrings = {} + # This is set at the last step of the publishing process. + self.versioninfo = "" + # we use the servermap to populate the initial goal: this way we will # try to update each existing share in place. for (peerid, shnum) in self._servermap.servermap: @@ -235,87 +453,439 @@ class Publish: self.bad_share_checkstrings[key] = old_checkstring self.connections[peerid] = self._servermap.connections[peerid] - # create the shares. We'll discard these as they are delivered. SDMF: - # we're allowed to hold everything in memory. + # TODO: Make this part do peer selection. + self.update_goal() + self.writers = {} + if self._version == MDMF_VERSION: + writer_class = MDMFSlotWriteProxy + else: + writer_class = SDMFSlotWriteProxy + + # For each (peerid, shnum) in self.goal, we make a + # write proxy for that peer. We'll use this to write + # shares to the peer. + for key in self.goal: + peerid, shnum = key + write_enabler = self._node.get_write_enabler(peerid) + renew_secret = self._node.get_renewal_secret(peerid) + cancel_secret = self._node.get_cancel_secret(peerid) + secrets = (write_enabler, renew_secret, cancel_secret) + self.writers[shnum] = writer_class(shnum, + self.connections[peerid], + self._storage_index, + secrets, + self._new_seqnum, + self.required_shares, + self.total_shares, + self.segment_size, + self.datalength) + self.writers[shnum].peerid = peerid + if (peerid, shnum) in self._servermap.servermap: + old_versionid, old_timestamp = self._servermap.servermap[key] + (old_seqnum, old_root_hash, old_salt, old_segsize, + old_datalength, old_k, old_N, old_prefix, + old_offsets_tuple) = old_versionid + self.writers[shnum].set_checkstring(old_seqnum, + old_root_hash, + old_salt) + elif (peerid, shnum) in self.bad_share_checkstrings: + old_checkstring = self.bad_share_checkstrings[(peerid, shnum)] + self.writers[shnum].set_checkstring(old_checkstring) + + # Our remote shares will not have a complete checkstring until + # after we are done writing share data and have started to write + # blocks. In the meantime, we need to know what to look for when + # writing, so that we can detect UncoordinatedWriteErrors. + self._checkstring = self.writers.values()[0].get_checkstring() + + # Now, we start pushing shares. self._status.timings["setup"] = time.time() - self._started - d = self._encrypt_and_encode() - d.addCallback(self._generate_shares) - def _start_pushing(res): - self._started_pushing = time.time() - return res - d.addCallback(_start_pushing) - d.addCallback(self.loop) # trigger delivery - d.addErrback(self._fatal_error) + # First, we encrypt, encode, and publish the shares that we need + # to encrypt, encode, and publish. + + # This will eventually hold the block hash chain for each share + # that we publish. We define it this way so that empty publishes + # will still have something to write to the remote slot. + self.blockhashes = dict([(i, []) for i in xrange(self.total_shares)]) + for i in xrange(self.total_shares): + blocks = self.blockhashes[i] + for j in xrange(self.num_segments): + blocks.append(None) + self.sharehash_leaves = None # eventually [sharehashes] + self.sharehashes = {} # shnum -> [sharehash leaves necessary to + # validate the share] + + self.log("Starting push") + + self._state = PUSHING_BLOCKS_STATE + self._push() return self.done_deferred - def setup_encoding_parameters(self): - segment_size = len(self.newdata) + + def _update_status(self): + self._status.set_status("Sending Shares: %d placed out of %d, " + "%d messages outstanding" % + (len(self.placed), + len(self.goal), + len(self.outstanding))) + self._status.set_progress(1.0 * len(self.placed) / len(self.goal)) + + + def setup_encoding_parameters(self, offset=0): + if self._version == MDMF_VERSION: + segment_size = DEFAULT_MAX_SEGMENT_SIZE # 128 KiB by default + else: + segment_size = self.datalength # SDMF is only one segment # this must be a multiple of self.required_shares segment_size = mathutil.next_multiple(segment_size, self.required_shares) self.segment_size = segment_size + + # Calculate the starting segment for the upload. if segment_size: - self.num_segments = mathutil.div_ceil(len(self.newdata), + # We use div_ceil instead of integer division here because + # it is semantically correct. + # If datalength isn't an even multiple of segment_size, but + # is larger than segment_size, datalength // segment_size + # will be the largest number such that num <= datalength and + # num % segment_size == 0. But that's not what we want, + # because it ignores the extra data. div_ceil will give us + # the right number of segments for the data that we're + # given. + self.num_segments = mathutil.div_ceil(self.datalength, segment_size) + + self.starting_segment = offset // segment_size + else: self.num_segments = 0 - assert self.num_segments in [0, 1,] # SDMF restrictions + self.starting_segment = 0 - def _fatal_error(self, f): - self.log("error during loop", failure=f, level=log.UNUSUAL) - self._done(f) - def _update_status(self): - self._status.set_status("Sending Shares: %d placed out of %d, " - "%d messages outstanding" % - (len(self.placed), - len(self.goal), - len(self.outstanding))) - self._status.set_progress(1.0 * len(self.placed) / len(self.goal)) + self.log("building encoding parameters for file") + self.log("got segsize %d" % self.segment_size) + self.log("got %d segments" % self.num_segments) - def loop(self, ignored=None): - self.log("entering loop", level=log.NOISY) - if not self._running: - return + if self._version == SDMF_VERSION: + assert self.num_segments in (0, 1) # SDMF + # calculate the tail segment size. + + if segment_size and self.datalength: + self.tail_segment_size = self.datalength % segment_size + self.log("got tail segment size %d" % self.tail_segment_size) + else: + self.tail_segment_size = 0 + + if self.tail_segment_size == 0 and segment_size: + # The tail segment is the same size as the other segments. + self.tail_segment_size = segment_size - self.looplimit -= 1 - if self.looplimit <= 0: - raise LoopLimitExceededError("loop limit exceeded") + # Make FEC encoders + fec = codec.CRSEncoder() + fec.set_params(self.segment_size, + self.required_shares, self.total_shares) + self.piece_size = fec.get_block_size() + self.fec = fec - if self.surprised: - # don't send out any new shares, just wait for the outstanding - # ones to be retired. - self.log("currently surprised, so don't send any new shares", - level=log.NOISY) + if self.tail_segment_size == self.segment_size: + self.tail_fec = self.fec else: - self.update_goal() - # how far are we from our goal? - needed = self.goal - self.placed - self.outstanding - self._update_status() - - if needed: - # we need to send out new shares - self.log(format="need to send %(needed)d new shares", - needed=len(needed), level=log.NOISY) - self._send_shares(needed) - return - - if self.outstanding: - # queries are still pending, keep waiting - self.log(format="%(outstanding)d queries still outstanding", - outstanding=len(self.outstanding), - level=log.NOISY) - return + tail_fec = codec.CRSEncoder() + tail_fec.set_params(self.tail_segment_size, + self.required_shares, + self.total_shares) + self.tail_fec = tail_fec + + self._current_segment = self.starting_segment + self.end_segment = self.num_segments - 1 + # Now figure out where the last segment should be. + if self.data.get_size() != self.datalength: + # We're updating a few segments in the middle of a mutable + # file, so we don't want to republish the whole thing. + # (we don't have enough data to do that even if we wanted + # to) + end = self.data.get_size() + self.end_segment = end // segment_size + if end % segment_size == 0: + self.end_segment -= 1 + + self.log("got start segment %d" % self.starting_segment) + self.log("got end segment %d" % self.end_segment) + + + def _push(self, ignored=None): + """ + I manage state transitions. In particular, I see that we still + have a good enough number of writers to complete the upload + successfully. + """ + # Can we still successfully publish this file? + # TODO: Keep track of outstanding queries before aborting the + # process. + if len(self.writers) < self.required_shares or self.surprised: + return self._failure() + + # Figure out what we need to do next. Each of these needs to + # return a deferred so that we don't block execution when this + # is first called in the upload method. + if self._state == PUSHING_BLOCKS_STATE: + return self.push_segment(self._current_segment) + + elif self._state == PUSHING_EVERYTHING_ELSE_STATE: + return self.push_everything_else() + + # If we make it to this point, we were successful in placing the + # file. + return self._done() + + + def push_segment(self, segnum): + if self.num_segments == 0 and self._version == SDMF_VERSION: + self._add_dummy_salts() + + if segnum > self.end_segment: + # We don't have any more segments to push. + self._state = PUSHING_EVERYTHING_ELSE_STATE + return self._push() + + d = self._encode_segment(segnum) + d.addCallback(self._push_segment, segnum) + def _increment_segnum(ign): + self._current_segment += 1 + # XXX: I don't think we need to do addBoth here -- any errBacks + # should be handled within push_segment. + d.addCallback(_increment_segnum) + d.addCallback(self._turn_barrier) + d.addCallback(self._push) + d.addErrback(self._failure) + + + def _turn_barrier(self, result): + """ + I help the publish process avoid the recursion limit issues + described in #237. + """ + return fireEventually(result) + + + def _add_dummy_salts(self): + """ + SDMF files need a salt even if they're empty, or the signature + won't make sense. This method adds a dummy salt to each of our + SDMF writers so that they can write the signature later. + """ + salt = os.urandom(16) + assert self._version == SDMF_VERSION + + for writer in self.writers.itervalues(): + writer.put_salt(salt) + + + def _encode_segment(self, segnum): + """ + I encrypt and encode the segment segnum. + """ + started = time.time() + + if segnum + 1 == self.num_segments: + segsize = self.tail_segment_size + else: + segsize = self.segment_size + + + self.log("Pushing segment %d of %d" % (segnum + 1, self.num_segments)) + data = self.data.read(segsize) + # XXX: This is dumb. Why return a list? + data = "".join(data) + + assert len(data) == segsize, len(data) + + salt = os.urandom(16) + + key = hashutil.ssk_readkey_data_hash(salt, self.readkey) + self._status.set_status("Encrypting") + enc = AES(key) + crypttext = enc.process(data) + assert len(crypttext) == len(data) - # no queries outstanding, no placements needed: we're done - self.log("no queries outstanding, no placements needed: done", - level=log.OPERATIONAL) now = time.time() - elapsed = now - self._started_pushing - self._status.timings["push"] = elapsed - return self._done(None) + self._status.timings["encrypt"] = now - started + started = now + + # now apply FEC + if segnum + 1 == self.num_segments: + fec = self.tail_fec + else: + fec = self.fec + + self._status.set_status("Encoding") + crypttext_pieces = [None] * self.required_shares + piece_size = fec.get_block_size() + for i in range(len(crypttext_pieces)): + offset = i * piece_size + piece = crypttext[offset:offset+piece_size] + piece = piece + "\x00"*(piece_size - len(piece)) # padding + crypttext_pieces[i] = piece + assert len(piece) == piece_size + d = fec.encode(crypttext_pieces) + def _done_encoding(res): + elapsed = time.time() - started + self._status.timings["encode"] = elapsed + return (res, salt) + d.addCallback(_done_encoding) + return d + + + def _push_segment(self, encoded_and_salt, segnum): + """ + I push (data, salt) as segment number segnum. + """ + results, salt = encoded_and_salt + shares, shareids = results + self._status.set_status("Pushing segment") + for i in xrange(len(shares)): + sharedata = shares[i] + shareid = shareids[i] + if self._version == MDMF_VERSION: + hashed = salt + sharedata + else: + hashed = sharedata + block_hash = hashutil.block_hash(hashed) + self.blockhashes[shareid][segnum] = block_hash + # find the writer for this share + writer = self.writers[shareid] + writer.put_block(sharedata, segnum, salt) + + + def push_everything_else(self): + """ + I put everything else associated with a share. + """ + self._pack_started = time.time() + self.push_encprivkey() + self.push_blockhashes() + self.push_sharehashes() + self.push_toplevel_hashes_and_signature() + d = self.finish_publishing() + def _change_state(ignored): + self._state = DONE_STATE + d.addCallback(_change_state) + d.addCallback(self._push) + return d + + + def push_encprivkey(self): + encprivkey = self._encprivkey + self._status.set_status("Pushing encrypted private key") + for writer in self.writers.itervalues(): + writer.put_encprivkey(encprivkey) + + + def push_blockhashes(self): + self.sharehash_leaves = [None] * len(self.blockhashes) + self._status.set_status("Building and pushing block hash tree") + for shnum, blockhashes in self.blockhashes.iteritems(): + t = hashtree.HashTree(blockhashes) + self.blockhashes[shnum] = list(t) + # set the leaf for future use. + self.sharehash_leaves[shnum] = t[0] + + writer = self.writers[shnum] + writer.put_blockhashes(self.blockhashes[shnum]) + + + def push_sharehashes(self): + self._status.set_status("Building and pushing share hash chain") + share_hash_tree = hashtree.HashTree(self.sharehash_leaves) + for shnum in xrange(len(self.sharehash_leaves)): + needed_indices = share_hash_tree.needed_hashes(shnum) + self.sharehashes[shnum] = dict( [ (i, share_hash_tree[i]) + for i in needed_indices] ) + writer = self.writers[shnum] + writer.put_sharehashes(self.sharehashes[shnum]) + self.root_hash = share_hash_tree[0] + + + def push_toplevel_hashes_and_signature(self): + # We need to to three things here: + # - Push the root hash and salt hash + # - Get the checkstring of the resulting layout; sign that. + # - Push the signature + self._status.set_status("Pushing root hashes and signature") + for shnum in xrange(self.total_shares): + writer = self.writers[shnum] + writer.put_root_hash(self.root_hash) + self._update_checkstring() + self._make_and_place_signature() + + + def _update_checkstring(self): + """ + After putting the root hash, MDMF files will have the + checkstring written to the storage server. This means that we + can update our copy of the checkstring so we can detect + uncoordinated writes. SDMF files will have the same checkstring, + so we need not do anything. + """ + self._checkstring = self.writers.values()[0].get_checkstring() + + + def _make_and_place_signature(self): + """ + I create and place the signature. + """ + started = time.time() + self._status.set_status("Signing prefix") + signable = self.writers[0].get_signable() + self.signature = self._privkey.sign(signable) + + for (shnum, writer) in self.writers.iteritems(): + writer.put_signature(self.signature) + self._status.timings['sign'] = time.time() - started + + + def finish_publishing(self): + # We're almost done -- we just need to put the verification key + # and the offsets + started = time.time() + self._status.set_status("Pushing shares") + self._started_pushing = started + ds = [] + verification_key = self._pubkey.serialize() + + + # TODO: Bad, since we remove from this same dict. We need to + # make a copy, or just use a non-iterated value. + for (shnum, writer) in self.writers.iteritems(): + writer.put_verification_key(verification_key) + d = writer.finish_publishing() + # Add the (peerid, shnum) tuple to our list of outstanding + # queries. This gets used by _loop if some of our queries + # fail to place shares. + self.outstanding.add((writer.peerid, writer.shnum)) + d.addCallback(self._got_write_answer, writer, started) + d.addErrback(self._connection_problem, writer) + ds.append(d) + self._record_verinfo() + self._status.timings['pack'] = time.time() - started + return defer.DeferredList(ds) + + + def _record_verinfo(self): + self.versioninfo = self.writers.values()[0].get_verinfo() + + + def _connection_problem(self, f, writer): + """ + We ran into a connection problem while working with writer, and + need to deal with that. + """ + self.log("found problem: %s" % str(f)) + self._last_failure = f + del(self.writers[writer.shnum]) + def log_goal(self, goal, message=""): logmsg = [message] @@ -398,286 +968,52 @@ class Publish: self.log_goal(self.goal, "after update: ") + def _got_write_answer(self, answer, writer, started): + if not answer: + # SDMF writers only pretend to write when readers set their + # blocks, salts, and so on -- they actually just write once, + # at the end of the upload process. In fake writes, they + # return defer.succeed(None). If we see that, we shouldn't + # bother checking it. + return - def _encrypt_and_encode(self): - # this returns a Deferred that fires with a list of (sharedata, - # sharenum) tuples. TODO: cache the ciphertext, only produce the - # shares that we care about. - self.log("_encrypt_and_encode") - - self._status.set_status("Encrypting") - started = time.time() - - key = hashutil.ssk_readkey_data_hash(self.salt, self.readkey) - enc = AES(key) - crypttext = enc.process(self.newdata) - assert len(crypttext) == len(self.newdata) + peerid = writer.peerid + lp = self.log("_got_write_answer from %s, share %d" % + (idlib.shortnodeid_b2a(peerid), writer.shnum)) now = time.time() - self._status.timings["encrypt"] = now - started - started = now - - # now apply FEC - - self._status.set_status("Encoding") - fec = codec.CRSEncoder() - fec.set_params(self.segment_size, - self.required_shares, self.total_shares) - piece_size = fec.get_block_size() - crypttext_pieces = [None] * self.required_shares - for i in range(len(crypttext_pieces)): - offset = i * piece_size - piece = crypttext[offset:offset+piece_size] - piece = piece + "\x00"*(piece_size - len(piece)) # padding - crypttext_pieces[i] = piece - assert len(piece) == piece_size - - d = fec.encode(crypttext_pieces) - def _done_encoding(res): - elapsed = time.time() - started - self._status.timings["encode"] = elapsed - return res - d.addCallback(_done_encoding) - return d - - def _generate_shares(self, shares_and_shareids): - # this sets self.shares and self.root_hash - self.log("_generate_shares") - self._status.set_status("Generating Shares") - started = time.time() - - # we should know these by now - privkey = self._privkey - encprivkey = self._encprivkey - pubkey = self._pubkey - - (shares, share_ids) = shares_and_shareids - - assert len(shares) == len(share_ids) - assert len(shares) == self.total_shares - all_shares = {} - block_hash_trees = {} - share_hash_leaves = [None] * len(shares) - for i in range(len(shares)): - share_data = shares[i] - shnum = share_ids[i] - all_shares[shnum] = share_data - - # build the block hash tree. SDMF has only one leaf. - leaves = [hashutil.block_hash(share_data)] - t = hashtree.HashTree(leaves) - block_hash_trees[shnum] = list(t) - share_hash_leaves[shnum] = t[0] - for leaf in share_hash_leaves: - assert leaf is not None - share_hash_tree = hashtree.HashTree(share_hash_leaves) - share_hash_chain = {} - for shnum in range(self.total_shares): - needed_hashes = share_hash_tree.needed_hashes(shnum) - share_hash_chain[shnum] = dict( [ (i, share_hash_tree[i]) - for i in needed_hashes ] ) - root_hash = share_hash_tree[0] - assert len(root_hash) == 32 - self.log("my new root_hash is %s" % base32.b2a(root_hash)) - self._new_version_info = (self._new_seqnum, root_hash, self.salt) - - prefix = pack_prefix(self._new_seqnum, root_hash, self.salt, - self.required_shares, self.total_shares, - self.segment_size, len(self.newdata)) - - # now pack the beginning of the share. All shares are the same up - # to the signature, then they have divergent share hash chains, - # then completely different block hash trees + salt + share data, - # then they all share the same encprivkey at the end. The sizes - # of everything are the same for all shares. - - sign_started = time.time() - signature = privkey.sign(prefix) - self._status.timings["sign"] = time.time() - sign_started - - verification_key = pubkey.serialize() - - final_shares = {} - for shnum in range(self.total_shares): - final_share = pack_share(prefix, - verification_key, - signature, - share_hash_chain[shnum], - block_hash_trees[shnum], - all_shares[shnum], - encprivkey) - final_shares[shnum] = final_share - elapsed = time.time() - started - self._status.timings["pack"] = elapsed - self.shares = final_shares - self.root_hash = root_hash - - # we also need to build up the version identifier for what we're - # pushing. Extract the offsets from one of our shares. - assert final_shares - offsets = unpack_header(final_shares.values()[0])[-1] - offsets_tuple = tuple( [(key,value) for key,value in offsets.items()] ) - verinfo = (self._new_seqnum, root_hash, self.salt, - self.segment_size, len(self.newdata), - self.required_shares, self.total_shares, - prefix, offsets_tuple) - self.versioninfo = verinfo - - - - def _send_shares(self, needed): - self.log("_send_shares") - - # we're finally ready to send out our shares. If we encounter any - # surprises here, it's because somebody else is writing at the same - # time. (Note: in the future, when we remove the _query_peers() step - # and instead speculate about [or remember] which shares are where, - # surprises here are *not* indications of UncoordinatedWriteError, - # and we'll need to respond to them more gracefully.) - - # needed is a set of (peerid, shnum) tuples. The first thing we do is - # organize it by peerid. - - peermap = DictOfSets() - for (peerid, shnum) in needed: - peermap.add(peerid, shnum) - - # the next thing is to build up a bunch of test vectors. The - # semantics of Publish are that we perform the operation if the world - # hasn't changed since the ServerMap was constructed (more or less). - # For every share we're trying to place, we create a test vector that - # tests to see if the server*share still corresponds to the - # map. - - all_tw_vectors = {} # maps peerid to tw_vectors - sm = self._servermap.servermap - - for key in needed: - (peerid, shnum) = key - - if key in sm: - # an old version of that share already exists on the - # server, according to our servermap. We will create a - # request that attempts to replace it. - old_versionid, old_timestamp = sm[key] - (old_seqnum, old_root_hash, old_salt, old_segsize, - old_datalength, old_k, old_N, old_prefix, - old_offsets_tuple) = old_versionid - old_checkstring = pack_checkstring(old_seqnum, - old_root_hash, - old_salt) - testv = (0, len(old_checkstring), "eq", old_checkstring) - - elif key in self.bad_share_checkstrings: - old_checkstring = self.bad_share_checkstrings[key] - testv = (0, len(old_checkstring), "eq", old_checkstring) - - else: - # add a testv that requires the share not exist - - # Unfortunately, foolscap-0.2.5 has a bug in the way inbound - # constraints are handled. If the same object is referenced - # multiple times inside the arguments, foolscap emits a - # 'reference' token instead of a distinct copy of the - # argument. The bug is that these 'reference' tokens are not - # accepted by the inbound constraint code. To work around - # this, we need to prevent python from interning the - # (constant) tuple, by creating a new copy of this vector - # each time. - - # This bug is fixed in foolscap-0.2.6, and even though this - # version of Tahoe requires foolscap-0.3.1 or newer, we are - # supposed to be able to interoperate with older versions of - # Tahoe which are allowed to use older versions of foolscap, - # including foolscap-0.2.5 . In addition, I've seen other - # foolscap problems triggered by 'reference' tokens (see #541 - # for details). So we must keep this workaround in place. - - #testv = (0, 1, 'eq', "") - testv = tuple([0, 1, 'eq', ""]) - - testvs = [testv] - # the write vector is simply the share - writev = [(0, self.shares[shnum])] - - if peerid not in all_tw_vectors: - all_tw_vectors[peerid] = {} - # maps shnum to (testvs, writevs, new_length) - assert shnum not in all_tw_vectors[peerid] - - all_tw_vectors[peerid][shnum] = (testvs, writev, None) - - # we read the checkstring back from each share, however we only use - # it to detect whether there was a new share that we didn't know - # about. The success or failure of the write will tell us whether - # there was a collision or not. If there is a collision, the first - # thing we'll do is update the servermap, which will find out what - # happened. We could conceivably reduce a roundtrip by using the - # readv checkstring to populate the servermap, but really we'd have - # to read enough data to validate the signatures too, so it wouldn't - # be an overall win. - read_vector = [(0, struct.calcsize(SIGNED_PREFIX))] - - # ok, send the messages! - self.log("sending %d shares" % len(all_tw_vectors), level=log.NOISY) - started = time.time() - for (peerid, tw_vectors) in all_tw_vectors.items(): - - write_enabler = self._node.get_write_enabler(peerid) - renew_secret = self._node.get_renewal_secret(peerid) - cancel_secret = self._node.get_cancel_secret(peerid) - secrets = (write_enabler, renew_secret, cancel_secret) - shnums = tw_vectors.keys() - - for shnum in shnums: - self.outstanding.add( (peerid, shnum) ) + elapsed = now - started - d = self._do_testreadwrite(peerid, secrets, - tw_vectors, read_vector) - d.addCallbacks(self._got_write_answer, self._got_write_error, - callbackArgs=(peerid, shnums, started), - errbackArgs=(peerid, shnums, started)) - # tolerate immediate errback, like with DeadReferenceError - d.addBoth(fireEventually) - d.addCallback(self.loop) - d.addErrback(self._fatal_error) + self._status.add_per_server_time(peerid, elapsed) - self._update_status() - self.log("%d shares sent" % len(all_tw_vectors), level=log.NOISY) - - def _do_testreadwrite(self, peerid, secrets, - tw_vectors, read_vector): - storage_index = self._storage_index - ss = self.connections[peerid] - - #print "SS[%s] is %s" % (idlib.shortnodeid_b2a(peerid), ss), ss.tracker.interfaceName - d = ss.callRemote("slot_testv_and_readv_and_writev", - storage_index, - secrets, - tw_vectors, - read_vector) - return d + wrote, read_data = answer - def _got_write_answer(self, answer, peerid, shnums, started): - lp = self.log("_got_write_answer from %s" % - idlib.shortnodeid_b2a(peerid)) - for shnum in shnums: - self.outstanding.discard( (peerid, shnum) ) + surprise_shares = set(read_data.keys()) - set([writer.shnum]) - now = time.time() - elapsed = now - started - self._status.add_per_server_time(peerid, elapsed) + # We need to remove from surprise_shares any shares that we are + # knowingly also writing to that peer from other writers. - wrote, read_data = answer + # TODO: Precompute this. + known_shnums = [x.shnum for x in self.writers.values() + if x.peerid == peerid] + surprise_shares -= set(known_shnums) + self.log("found the following surprise shares: %s" % + str(surprise_shares)) - surprise_shares = set(read_data.keys()) - set(shnums) + # Now surprise shares contains all of the shares that we did not + # expect to be there. surprised = False for shnum in surprise_shares: # read_data is a dict mapping shnum to checkstring (SIGNED_PREFIX) checkstring = read_data[shnum][0] - their_version_info = unpack_checkstring(checkstring) - if their_version_info == self._new_version_info: + # What we want to do here is to see if their (seqnum, + # roothash, salt) is the same as our (seqnum, roothash, + # salt), or the equivalent for MDMF. The best way to do this + # is to store a packed representation of our checkstring + # somewhere, then not bother unpacking the other + # checkstring. + if checkstring == self._checkstring: # they have the right share, somehow if (peerid,shnum) in self.goal: @@ -756,7 +1092,7 @@ class Publish: self.log("our testv failed, so the write did not happen", parent=lp, level=log.WEIRD, umid="8sc26g") self.surprised = True - self.bad_peers.add(peerid) # don't ask them again + self.bad_peers.add(writer) # don't ask them again # use the checkstring to add information to the log message for (shnum,readv) in read_data.items(): checkstring = readv[0] @@ -778,53 +1114,237 @@ class Publish: # if expected_version==None, then we didn't expect to see a # share on that peer, and the 'surprise_shares' clause above # will have logged it. - # self.loop() will take care of finding new homes return - for shnum in shnums: - self.placed.add( (peerid, shnum) ) - # and update the servermap - self._servermap.add_new_share(peerid, shnum, + # and update the servermap + # self.versioninfo is set during the last phase of publishing. + # If we get there, we know that responses correspond to placed + # shares, and can safely execute these statements. + if self.versioninfo: + self.log("wrote successfully: adding new share to servermap") + self._servermap.add_new_share(peerid, writer.shnum, self.versioninfo, started) - - # self.loop() will take care of checking to see if we're done - return - - def _got_write_error(self, f, peerid, shnums, started): - for shnum in shnums: - self.outstanding.discard( (peerid, shnum) ) - self.bad_peers.add(peerid) - if self._first_write_error is None: - self._first_write_error = f - self.log(format="error while writing shares %(shnums)s to peerid %(peerid)s", - shnums=list(shnums), peerid=idlib.shortnodeid_b2a(peerid), - failure=f, - level=log.UNUSUAL) - # self.loop() will take care of checking to see if we're done + self.placed.add( (peerid, writer.shnum) ) + self._update_status() + # the next method in the deferred chain will check to see if + # we're done and successful. return - def _done(self, res): + def _done(self): if not self._running: return self._running = False now = time.time() self._status.timings["total"] = now - self._started + + elapsed = now - self._started_pushing + self._status.timings['push'] = elapsed + self._status.set_active(False) - if isinstance(res, failure.Failure): - self.log("Publish done, with failure", failure=res, - level=log.WEIRD, umid="nRsR9Q") - self._status.set_status("Failed") - elif self.surprised: - self.log("Publish done, UncoordinatedWriteError", level=log.UNUSUAL) - self._status.set_status("UncoordinatedWriteError") - # deliver a failure - res = failure.Failure(UncoordinatedWriteError()) - # TODO: recovery + self.log("Publish done, success") + self._status.set_status("Finished") + self._status.set_progress(1.0) + # Get k and segsize, then give them to the caller. + hints = {} + hints['segsize'] = self.segment_size + hints['k'] = self.required_shares + self._node.set_downloader_hints(hints) + eventually(self.done_deferred.callback, None) + + def _failure(self, f=None): + if f: + self._last_failure = f + + if not self.surprised: + # We ran out of servers + msg = "Publish ran out of good servers" + if self._last_failure: + msg += ", last failure was: %s" % str(self._last_failure) + self.log(msg) + e = NotEnoughServersError(msg) + else: - self.log("Publish done, success") - self._status.set_status("Finished") - self._status.set_progress(1.0) - eventually(self.done_deferred.callback, res) + # We ran into shares that we didn't recognize, which means + # that we need to return an UncoordinatedWriteError. + self.log("Publish failed with UncoordinatedWriteError") + e = UncoordinatedWriteError() + f = failure.Failure(e) + eventually(self.done_deferred.callback, f) + + +class MutableFileHandle: + """ + I am a mutable uploadable built around a filehandle-like object, + usually either a StringIO instance or a handle to an actual file. + """ + implements(IMutableUploadable) + + def __init__(self, filehandle): + # The filehandle is defined as a generally file-like object that + # has these two methods. We don't care beyond that. + assert hasattr(filehandle, "read") + assert hasattr(filehandle, "close") + + self._filehandle = filehandle + # We must start reading at the beginning of the file, or we risk + # encountering errors when the data read does not match the size + # reported to the uploader. + self._filehandle.seek(0) + + # We have not yet read anything, so our position is 0. + self._marker = 0 + + + def get_size(self): + """ + I return the amount of data in my filehandle. + """ + if not hasattr(self, "_size"): + old_position = self._filehandle.tell() + # Seek to the end of the file by seeking 0 bytes from the + # file's end + self._filehandle.seek(0, 2) # 2 == os.SEEK_END in 2.5+ + self._size = self._filehandle.tell() + # Restore the previous position, in case this was called + # after a read. + self._filehandle.seek(old_position) + assert self._filehandle.tell() == old_position + + assert hasattr(self, "_size") + return self._size + + + def pos(self): + """ + I return the position of my read marker -- i.e., how much data I + have already read and returned to callers. + """ + return self._marker + def read(self, length): + """ + I return some data (up to length bytes) from my filehandle. + + In most cases, I return length bytes, but sometimes I won't -- + for example, if I am asked to read beyond the end of a file, or + an error occurs. + """ + results = self._filehandle.read(length) + self._marker += len(results) + return [results] + + + def close(self): + """ + I close the underlying filehandle. Any further operations on the + filehandle fail at this point. + """ + self._filehandle.close() + + +class MutableData(MutableFileHandle): + """ + I am a mutable uploadable built around a string, which I then cast + into a StringIO and treat as a filehandle. + """ + + def __init__(self, s): + # Take a string and return a file-like uploadable. + assert isinstance(s, str) + + MutableFileHandle.__init__(self, StringIO(s)) + + +class TransformingUploadable: + """ + I am an IMutableUploadable that wraps another IMutableUploadable, + and some segments that are already on the grid. When I am called to + read, I handle merging of boundary segments. + """ + implements(IMutableUploadable) + + + def __init__(self, data, offset, segment_size, start, end): + assert IMutableUploadable.providedBy(data) + + self._newdata = data + self._offset = offset + self._segment_size = segment_size + self._start = start + self._end = end + + self._read_marker = 0 + + self._first_segment_offset = offset % segment_size + + num = self.log("TransformingUploadable: starting", parent=None) + self._log_number = num + self.log("got fso: %d" % self._first_segment_offset) + self.log("got offset: %d" % self._offset) + + + def log(self, *args, **kwargs): + if 'parent' not in kwargs: + kwargs['parent'] = self._log_number + if "facility" not in kwargs: + kwargs["facility"] = "tahoe.mutable.transforminguploadable" + return log.msg(*args, **kwargs) + + + def get_size(self): + return self._offset + self._newdata.get_size() + + + def read(self, length): + # We can get data from 3 sources here. + # 1. The first of the segments provided to us. + # 2. The data that we're replacing things with. + # 3. The last of the segments provided to us. + + # are we in state 0? + self.log("reading %d bytes" % length) + + old_start_data = "" + old_data_length = self._first_segment_offset - self._read_marker + if old_data_length > 0: + if old_data_length > length: + old_data_length = length + self.log("returning %d bytes of old start data" % old_data_length) + + old_data_end = old_data_length + self._read_marker + old_start_data = self._start[self._read_marker:old_data_end] + length -= old_data_length + else: + # otherwise calculations later get screwed up. + old_data_length = 0 + + # Is there enough new data to satisfy this read? If not, we need + # to pad the end of the data with data from our last segment. + old_end_length = length - \ + (self._newdata.get_size() - self._newdata.pos()) + old_end_data = "" + if old_end_length > 0: + self.log("reading %d bytes of old end data" % old_end_length) + + # TODO: We're not explicitly checking for tail segment size + # here. Is that a problem? + old_data_offset = (length - old_end_length + \ + old_data_length) % self._segment_size + self.log("reading at offset %d" % old_data_offset) + old_end = old_data_offset + old_end_length + old_end_data = self._end[old_data_offset:old_end] + length -= old_end_length + assert length == self._newdata.get_size() - self._newdata.pos() + + self.log("reading %d bytes of new data" % length) + new_data = self._newdata.read(length) + new_data = "".join(new_data) + + self._read_marker += len(old_start_data + new_data + old_end_data) + + return old_start_data + new_data + old_end_data + + def close(self): + pass