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183 lines
10 KiB
Plaintext
183 lines
10 KiB
Plaintext
The "Denver Airport" Protocol
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(discussed whilst returning robk to DEN, 12/1/06)
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This is a scaling improvement on the "Select Peers" phase of Tahoe2. The
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problem it tries to address is the storage and maintenance of the 1M-long
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peer list, and the relative difficulty of gathering long-term reliability
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information on a useful numbers of those peers.
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In DEN, each node maintains a Chord-style set of connections to other nodes:
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log2(N) "finger" connections to distant peers (the first of which is halfway
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across the ring, the second is 1/4 across, then 1/8th, etc). These
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connections need to be kept alive with relatively short timeouts (5s?), so
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any breaks can be rejoined quickly. In addition to the finger connections,
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each node must also remain aware of K "successor" nodes (those which are
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immediately clockwise of the starting point). The node is not required to
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maintain connections to these, but it should remain informed about their
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contact information, so that it can create connections when necessary. We
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probably need a connection open to the immediate successor at all times.
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Since inbound connections exist too, each node has something like 2*log2(N)
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plus up to 2*K connections.
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Each node keeps history of uptime/availability of the nodes that it remains
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connected to. Each message that is sent to these peers includes an estimate
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of that peer's availability from the point of view of the outside world. The
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receiving node will average these reports together to determine what kind of
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reliability they should announce to anyone they accept leases for. This
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reliability is expressed as a percentage uptime: P=1.0 means the peer is
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available 24/7, P=0.0 means it is almost never reachable.
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When a node wishes to publish a file, it creates a list of (verifierid,
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sharenum) tuples, and computes a hash of each tuple. These hashes then
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represent starting points for the landlord search:
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starting_points = [(sharenum,sha(verifierid + str(sharenum)))
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for sharenum in range(256)]
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The node then constructs a reservation message that contains enough
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information for the potential landlord to evaluate the lease, *and* to make a
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connection back to the starting node:
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message = [verifierid, sharesize, requestor_furl, starting_points]
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The node looks through its list of finger connections and splits this message
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into up to log2(N) smaller messages, each of which contains only the starting
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points that should be sent to that finger connection. Specifically we sent a
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starting_point to a finger A if the nodeid of that finger is <= the
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starting_point and if the next finger B is > starting_point. Each message
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sent out can contain multiple starting_points, each for a different share.
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When a finger node receives this message, it performs the same splitting
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algorithm, sending each starting_point to other fingers. Eventually a
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starting_point is received by a node that knows that the starting_point lies
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between itself and its immediate successor. At this point the message
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switches from the "hop" mode (following fingers) to the "search" mode
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(following successors).
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While in "search" mode, each node interprets the message as a lease request.
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It checks its storage pool to see if it can accomodate the reservation. If
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so, it uses requestor_furl to contact the originator and announces its
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willingness to host the given sharenum. This message will include the
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reliability measurement derived from the host's counterclockwise neighbors.
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If the recipient cannot host the share, it forwards the request on to the
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next successor, which repeats the cycle. Each message has a maximum hop count
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which limits the number of peers which may be searched before giving up. If a
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node sees itself to be the last such hop, it must establish a connection to
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the originator and let them know that this sharenum could not be hosted.
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The originator sends out something like 100 or 200 starting points, and
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expects to get back responses (positive or negative) in a reasonable amount
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of time. (perhaps if we receive half of the responses in time T, wait for a
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total of 2T for the remaining ones). If no response is received with the
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timeout, either re-send the requests for those shares (to different fingers)
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or send requests for completely different shares.
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Each share represents some fraction of a point "S", such that the points for
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enough shares to reconstruct the whole file total to 1.0 points. I.e., if we
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construct 100 shares such that we need 25 of them to reconstruct the file,
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then each share represents .04 points.
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As the positive responses come in, we accumulate two counters: the capacity
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counter (which gets a full S points for each positive response), and the
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reliability counter (which gets S*(reliability-of-host) points). The capacity
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counter is not allowed to go above some limit (like 4x), as determined by
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provisioning. The node keeps adding leases until the reliability counter has
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gone above some other threshold (larger but close to 1.0).
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[ at download time, each host will be able to provide the share back with
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probability P times an exponential decay factor related to peer death. Sum
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these probabilities to get the average number of shares that will be
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available. The interesting thing is actually the distribution of these
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probabilities, and what threshold you have to pick to get a sufficiently
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high chance of recovering the file. If there are N identical peers with
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probability P, the number of recovered shares will have a gaussian
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distribution with an average of N*P and a stddev of (??). The PMF of this
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function is an S-curve, with a sharper slope when N is large. The
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probability of recovering the file is the value of this S curve at the
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threshold value (the number of necessary shares).
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P is not actually constant across all peers, rather we assume that it has
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its own distribution: maybe gaussian, more likely exponential (power law).
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This changes the shape of the S-curve. Assuming that we can characterize
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the distribution of P with perhaps two parameters (say meanP and stddevP),
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the S-curve is a function of meanP, stddevP, N, and threshold...
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To get 99.99% or 99.999% recoverability, we must choose a threshold value
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high enough to accomodate the random variations and uncertainty about the
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real values of P for each of the hosts we've selected. By counting
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reliability points, we are trying to estimate meanP/stddevP, so we know
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which S-curve to look at. The threshold is fixed at 1.0, since that's what
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erasure coding tells us we need to recover the file. The job is then to add
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hosts (increasing N and possibly changing meanP/stddevP) until our
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recoverability probability is as high as we want.
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]
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The originator takes all acceptance messages and adds them in order to the
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list of landlords that will be used to host the file. It stops when it gets
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enough reliability points. Note that it does *not* discriminate against
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unreliable hosts: they are less likely to have been found in the first place,
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so we don't need to discriminate against them a second time. We do, however,
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use the reliability points to acknowledge that sending data to an unreliable
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peer is not as useful as sending it to a reliable one (there is still value
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in doing so, though). The remaining reservation-acceptance messages are
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cancelled and then put aside: if we need to make a second pass, we ask those
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peers first.
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Shares are then created and published as in Tahoe2. If we lose a connection
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during the encoding, that share is lost. If we lose enough shares, we might
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want to generate more to make up for them: this is done by using the leftover
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acceptance messages first, then triggering a new Chord search for the
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as-yet-unaccepted sharenums. These new peers will get shares from all
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segments that have not yet been finished, then a second pass will be made to
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catch them up on the earlier segments.
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Properties of this approach:
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the total number of peers that each node must know anything about is bounded
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to something like 2*log2(N) + K, probably on the order of 50 to 100 total.
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This is the biggest advantage, since in tahoe2 each node must know at least
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the nodeid of all 1M peers. The maintenance traffic should be much less as a
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result.
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each node must maintain open (keep-alived) connections to something like
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2*log2(N) peers. In tahoe2, this number is 0 (well, probably 1 for the
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introducer).
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during upload, each node must actively use 100 connections to a random set
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of peers to push data (just like tahoe2).
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The probability that any given share-request gets a response is equal to the
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number of hops it travels through times the chance that a peer dies while
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holding on to the message. This should be pretty small, as the message
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should only be held by a peer for a few seconds (more if their network is
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busy). In tahoe2, each share-request always gets a response, since they are
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made directly to the target.
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I visualize the peer-lookup process as the originator creating a
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message-in-a-bottle for each share. Each message says "Dear Sir/Madam, I
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would like to store X bytes of data for file Y (share #Z) on a system close
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to (but not below) nodeid STARTING_POINT. If you find this amenable, please
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contact me at FURL so we can make arrangements.". These messages are then
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bundled together according to their rough destination (STARTING_POINT) and
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sent somewhere in the right direction.
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Download happens the same way: lookup messages are disseminated towards the
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STARTING_POINT and then search one successor at a time from there. There are
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two ways that the share might go missing: if the node is now offline (or has
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for some reason lost its shares), or if new nodes have joined since the
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original upload and the search depth (maximum hop count) is too small to
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accomodate the churn. Both result in the same amount of localized traffic. In
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the latter case, a storage node might want to migrate the share closer to the
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starting point, or perhaps just send them a note to remember a pointer for
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the share.
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Checking: anyone who wishes to do a filecheck needs to send out a lookup
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message for every potential share. These lookup messages could have a higher
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search depth than usual. It would be useful to know how many peers each
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message went through before being returned: this might be useful to perform
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repair by instructing the old host (which is further from the starting point
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than you'd like) to push their share closer towards the starting point.
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