# -*- test-case-name: allmydata.test.test_encode -*- from zope.interface import implements from twisted.internet import defer from twisted.python import log from allmydata.hashtree import HashTree, block_hash from allmydata.Crypto.Cipher import AES from allmydata.util import mathutil from allmydata.util.assertutil import _assert from allmydata.codec import CRSEncoder from allmydata.interfaces import IEncoder """ The goal of the encoder is to turn the original file into a series of 'shares'. Each share is going to a 'shareholder' (nominally each shareholder is a different host, but for small grids there may be overlap). The number of shares is chosen to hit our reliability goals (more shares on more machines means more reliability), and is limited by overhead (proportional to numshares or log(numshares)) and the encoding technology in use (Reed-Solomon only permits 256 shares total). It is also constrained by the amount of data we want to send to each host. For estimating purposes, think of 100 shares out of which we need 25 to reconstruct the file. The encoder starts by cutting the original file into segments. All segments except the last are of equal size. The segment size is chosen to constrain the memory footprint (which will probably vary between 1x and 4x segment size) and to constrain the overhead (which will be proportional to either the number of segments or log(number of segments)). Each segment (A,B,C) is read into memory, encrypted, and encoded into blocks. The 'share' (say, share #1) that makes it out to a host is a collection of these blocks (block A1, B1, C1), plus some hash-tree information necessary to validate the data upon retrieval. Only one segment is handled at a time: all blocks for segment A are delivered before any work is begun on segment B. As blocks are created, we retain the hash of each one. The list of block hashes for a single share (say, hash(A1), hash(B1), hash(C1)) is used to form the base of a Merkle hash tree for that share (hashtrees[1]). This hash tree has one terminal leaf per block. The complete block hash tree is sent to the shareholder after all the data has been sent. At retrieval time, the decoder will ask for specific pieces of this tree before asking for blocks, whichever it needs to validate those blocks. (Note: we don't really need to generate this whole block hash tree ourselves. It would be sufficient to have the shareholder generate it and just tell us the root. This gives us an extra level of validation on the transfer, though, and it is relatively cheap to compute.) Each of these block hash trees has a root hash. The collection of these root hashes for all shares are collected into the 'share hash tree', which has one terminal leaf per share. After sending the blocks and the complete block hash tree to each shareholder, we send them the portion of the share hash tree that is necessary to validate their share. The root of the share hash tree is put into the URI. """ KiB=1024 MiB=1024*KiB GiB=1024*MiB TiB=1024*GiB PiB=1024*TiB class Encoder(object): implements(IEncoder) NEEDED_SHARES = 25 TOTAL_SHARES = 100 MAX_SEGMENT_SIZE = 2*MiB def __init__(self, options={}): object.__init__(self) self.MAX_SEGMENT_SIZE = options.get("max_segment_size", self.MAX_SEGMENT_SIZE) k,n = options.get("needed_and_total_shares", (self.NEEDED_SHARES, self.TOTAL_SHARES)) self.NEEDED_SHARES = k self.TOTAL_SHARES = n def setup(self, infile, encryption_key): self.infile = infile assert isinstance(encryption_key, str) assert len(encryption_key) == 16 # AES-128 self.key = encryption_key infile.seek(0, 2) self.file_size = infile.tell() infile.seek(0, 0) self.num_shares = self.TOTAL_SHARES self.required_shares = self.NEEDED_SHARES self.segment_size = min(self.MAX_SEGMENT_SIZE, self.file_size) # this must be a multiple of self.required_shares self.segment_size = mathutil.next_multiple(self.segment_size, self.required_shares) self.setup_codec() def setup_codec(self): assert self.segment_size % self.required_shares == 0 self._codec = CRSEncoder() self._codec.set_params(self.segment_size, self.required_shares, self.num_shares) # the "tail" is the last segment. This segment may or may not be # shorter than all other segments. We use the "tail codec" to handle # it. If the tail is short, we use a different codec instance. In # addition, the tail codec must be fed data which has been padded out # to the right size. self.tail_size = self.file_size % self.segment_size if not self.tail_size: self.tail_size = self.segment_size # the tail codec is responsible for encoding tail_size bytes padded_tail_size = mathutil.next_multiple(self.tail_size, self.required_shares) self._tail_codec = CRSEncoder() self._tail_codec.set_params(padded_tail_size, self.required_shares, self.num_shares) def get_share_size(self): share_size = mathutil.div_ceil(self.file_size, self.required_shares) overhead = self.compute_overhead() return share_size + overhead def compute_overhead(self): return 0 def get_block_size(self): return self._codec.get_block_size() def set_shareholders(self, landlords): assert isinstance(landlords, dict) for k in landlords: # it would be nice to: #assert RIBucketWriter.providedBy(landlords[k]) pass self.landlords = landlords.copy() def start(self): #paddedsize = self._size + mathutil.pad_size(self._size, self.needed_shares) self.num_segments = mathutil.div_ceil(self.file_size, self.segment_size) self.share_size = mathutil.div_ceil(self.file_size, self.required_shares) self.setup_encryption() self.setup_codec() d = defer.succeed(None) for i in range(self.num_segments-1): # note to self: this form doesn't work, because lambda only # captures the slot, not the value #d.addCallback(lambda res: self.do_segment(i)) # use this form instead: d.addCallback(lambda res, i=i: self.do_segment(i)) d.addCallback(lambda res: self.do_tail_segment(self.num_segments-1)) d.addCallback(lambda res: self.send_all_subshare_hash_trees()) d.addCallback(lambda res: self.send_all_share_hash_trees()) d.addCallback(lambda res: self.close_all_shareholders()) d.addCallbacks(lambda res: self.done(), self.err) return d def setup_encryption(self): self.cryptor = AES.new(key=self.key, mode=AES.MODE_CTR, counterstart="\x00"*16) self.segment_num = 0 self.subshare_hashes = [[] for x in range(self.num_shares)] # subshare_hashes[i] is a list that will be accumulated and then send # to landlord[i]. This list contains a hash of each segment_share # that we sent to that landlord. self.share_root_hashes = [None] * self.num_shares def do_segment(self, segnum): chunks = [] codec = self._codec # the ICodecEncoder API wants to receive a total of self.segment_size # bytes on each encode() call, broken up into a number of # identically-sized pieces. Due to the way the codec algorithm works, # these pieces need to be the same size as the share which the codec # will generate. Therefore we must feed it with input_piece_size that # equals the output share size. input_piece_size = codec.get_block_size() # as a result, the number of input pieces per encode() call will be # equal to the number of required shares with which the codec was # constructed. You can think of the codec as chopping up a # 'segment_size' of data into 'required_shares' shares (not doing any # fancy math at all, just doing a split), then creating some number # of additional shares which can be substituted if the primary ones # are unavailable for i in range(self.required_shares): input_piece = self.infile.read(input_piece_size) # non-tail segments should be the full segment size assert len(input_piece) == input_piece_size encrypted_piece = self.cryptor.encrypt(input_piece) chunks.append(encrypted_piece) d = codec.encode(chunks) d.addCallback(self._encoded_segment, segnum) return d def do_tail_segment(self, segnum): chunks = [] codec = self._tail_codec input_piece_size = codec.get_block_size() for i in range(self.required_shares): input_piece = self.infile.read(input_piece_size) if len(input_piece) < input_piece_size: # padding input_piece += ('\x00' * (input_piece_size - len(input_piece))) encrypted_piece = self.cryptor.encrypt(input_piece) chunks.append(encrypted_piece) d = codec.encode(chunks) d.addCallback(self._encoded_segment, segnum) return d def _encoded_segment(self, (shares, shareids), segnum): # To generate the URI, we must generate the roothash, so we must # generate all shares, even if we aren't actually giving them to # anybody. This means that the set of share we create will be equal # to or larger than the set of landlords. If we have any landlord who # *doesn't* have a share, that's an error. _assert(set(self.landlords.keys()).issubset(set(shareids)), shareids=shareids, landlords=self.landlords) dl = [] for i in range(len(shares)): subshare = shares[i] shareid = shareids[i] d = self.send_subshare(shareid, segnum, subshare) dl.append(d) subshare_hash = block_hash(subshare) self.subshare_hashes[shareid].append(subshare_hash) dl = defer.DeferredList(dl) def _logit(res): log.msg("%s uploaded %s / %s bytes of your file." % (self, self.segment_size*(segnum+1), self.segment_size*self.num_segments)) return res dl.addCallback(_logit) return dl def send_subshare(self, shareid, segment_num, subshare): if shareid not in self.landlords: return defer.succeed(None) sh = self.landlords[shareid] return sh.callRemote("put_block", segment_num, subshare) def send_all_subshare_hash_trees(self): log.msg("%s sending subshare hash trees" % self) dl = [] for shareid,hashes in enumerate(self.subshare_hashes): # hashes is a list of the hashes of all subshares that were sent # to shareholder[shareid]. dl.append(self.send_one_subshare_hash_tree(shareid, hashes)) return defer.DeferredList(dl) def send_one_subshare_hash_tree(self, shareid, subshare_hashes): t = HashTree(subshare_hashes) all_hashes = list(t) # all_hashes[0] is the root hash, == hash(ah[1]+ah[2]) # all_hashes[1] is the left child, == hash(ah[3]+ah[4]) # all_hashes[n] == hash(all_hashes[2*n+1] + all_hashes[2*n+2]) self.share_root_hashes[shareid] = t[0] if shareid not in self.landlords: return defer.succeed(None) sh = self.landlords[shareid] return sh.callRemote("put_block_hashes", all_hashes) def send_all_share_hash_trees(self): # each bucket gets a set of share hash tree nodes that are needed to # validate their share. This includes the share hash itself, but does # not include the top-level hash root (which is stored securely in # the URI instead). log.msg("%s sending all share hash trees" % self) dl = [] for h in self.share_root_hashes: assert h # create the share hash tree t = HashTree(self.share_root_hashes) # the root of this hash tree goes into our URI self.root_hash = t[0] # now send just the necessary pieces out to each shareholder for i in range(self.num_shares): # the HashTree is given a list of leaves: 0,1,2,3..n . # These become nodes A+0,A+1,A+2.. of the tree, where A=n-1 needed_hash_indices = t.needed_hashes(i, include_leaf=True) hashes = [(hi, t[hi]) for hi in needed_hash_indices] dl.append(self.send_one_share_hash_tree(i, hashes)) return defer.DeferredList(dl) def send_one_share_hash_tree(self, shareid, needed_hashes): if shareid not in self.landlords: return defer.succeed(None) sh = self.landlords[shareid] return sh.callRemote("put_share_hashes", needed_hashes) def close_all_shareholders(self): log.msg("%s: closing shareholders" % self) dl = [] for shareid in self.landlords: dl.append(self.landlords[shareid].callRemote("close")) return defer.DeferredList(dl) def done(self): log.msg("%s: upload done" % self) return self.root_hash def err(self, f): log.msg("%s: upload failed: %s" % (self, f)) return f