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391 lines
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391 lines
20 KiB
Plaintext
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(protocol proposal, work-in-progress, not authoritative)
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(this document describes DSA-based mutable files, as opposed to the RSA-based
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mutable files that were introduced in tahoe-0.7.0 . This proposal has not yet
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been implemented. Please see mutable-DSA.svg for a quick picture of the
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crypto scheme described herein)
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This file shows only the differences from RSA-based mutable files to
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(EC)DSA-based mutable files. You have to read and understand
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docs/specifications/mutable.rst before reading this file (mutable-DSA.txt).
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== new design criteria ==
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* provide for variable number of semiprivate sections?
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* put e.g. filenames in one section, readcaps in another, writecaps in a third
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(ideally, to modify a filename you'd only have to modify one section, and
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we'd make encrypting/hashing more efficient by doing it on larger blocks of
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data, preferably one segment at a time instead of one writecap at a time)
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* cleanly distinguish between "container" (leases, write-enabler) and
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"slot contents" (everything that comes from share encoding)
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* sign all slot bits (to allow server-side verification)
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* someone reading the whole file should be able to read the share in a single
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linear pass with just a single seek to zero
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* writing the file should occur in two passes (3 seeks) in mostly linear order
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1: write version/pubkey/topbits/salt
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2: write zeros / seek+prefill where the hashchain/tree goes
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3: write blocks
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4: seek back
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5: write hashchain/tree
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* storage format: consider putting container bits in a separate file
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- $SI.index (contains list of shnums, leases, other-cabal-members, WE, etc)
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- $SI-$shnum.share (actual share data)
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* possible layout:
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- version
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- pubkey
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- topbits (k, N, size, segsize, etc)
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- salt? (salt tree root?)
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- share hash root
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- share hash chain
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- block hash tree
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- (salts?) (salt tree?)
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- blocks
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- signature (of [version .. share hash root])
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=== SDMF slots overview ===
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Each SDMF slot is created with a DSA public/private key pair, using a
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system-wide common modulus and generator, in which the private key is a
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random 256 bit number, and the public key is a larger value (about 2048 bits)
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that can be derived with a bit of math from the private key. The public key
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is known as the "verification key", while the private key is called the
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"signature key".
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The 256-bit signature key is used verbatim as the "write capability". This
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can be converted into the 2048ish-bit verification key through a fairly cheap
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set of modular exponentiation operations; this is done any time the holder of
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the write-cap wants to read the data. (Note that the signature key can either
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be a newly-generated random value, or the hash of something else, if we found
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a need for a capability that's stronger than the write-cap).
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This results in a write-cap which is 256 bits long and can thus be expressed
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in an ASCII/transport-safe encoded form (base62 encoding, fits in 72
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characters, including a local-node http: convenience prefix).
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The private key is hashed to form a 256-bit "salt". The public key is also
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hashed to form a 256-bit "pubkey hash". These two values are concatenated,
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hashed, and truncated to 192 bits to form the first 192 bits of the read-cap.
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The pubkey hash is hashed by itself and truncated to 64 bits to form the last
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64 bits of the read-cap. The full read-cap is 256 bits long, just like the
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write-cap.
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The first 192 bits of the read-cap are hashed and truncated to form the first
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192 bits of the "traversal cap". The last 64 bits of the read-cap are hashed
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to form the last 64 bits of the traversal cap. This gives us a 256-bit
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traversal cap.
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The first 192 bits of the traversal-cap are hashed and truncated to form the
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first 64 bits of the storage index. The last 64 bits of the traversal-cap are
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hashed to form the last 64 bits of the storage index. This gives us a 128-bit
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storage index.
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The verification-cap is the first 64 bits of the storage index plus the
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pubkey hash, 320 bits total. The verification-cap doesn't need to be
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expressed in a printable transport-safe form, so it's ok that it's longer.
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The read-cap is hashed one way to form an AES encryption key that is used to
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encrypt the salt; this key is called the "salt key". The encrypted salt is
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stored in the share. The private key never changes, therefore the salt never
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changes, and the salt key is only used for a single purpose, so there is no
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need for an IV.
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The read-cap is hashed a different way to form the master data encryption
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key. A random "data salt" is generated each time the share's contents are
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replaced, and the master data encryption key is concatenated with the data
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salt, then hashed, to form the AES CTR-mode "read key" that will be used to
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encrypt the actual file data. This is to avoid key-reuse. An outstanding
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issue is how to avoid key reuse when files are modified in place instead of
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being replaced completely; this is not done in SDMF but might occur in MDMF.
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The master data encryption key is used to encrypt data that should be visible
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to holders of a write-cap or a read-cap, but not to holders of a
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traversal-cap.
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The private key is hashed one way to form the salt, and a different way to
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form the "write enabler master". For each storage server on which a share is
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kept, the write enabler master is concatenated with the server's nodeid and
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hashed, and the result is called the "write enabler" for that particular
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server. Note that multiple shares of the same slot stored on the same server
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will all get the same write enabler, i.e. the write enabler is associated
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with the "bucket", rather than the individual shares.
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The private key is hashed a third way to form the "data write key", which can
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be used by applications which wish to store some data in a form that is only
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available to those with a write-cap, and not to those with merely a read-cap.
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This is used to implement transitive read-onlyness of dirnodes.
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The traversal cap is hashed to work the "traversal key", which can be used by
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applications that wish to store data in a form that is available to holders
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of a write-cap, read-cap, or traversal-cap.
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The idea is that dirnodes will store child write-caps under the writekey,
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child names and read-caps under the read-key, and verify-caps (for files) or
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deep-verify-caps (for directories) under the traversal key. This would give
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the holder of a root deep-verify-cap the ability to create a verify manifest
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for everything reachable from the root, but not the ability to see any
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plaintext or filenames. This would make it easier to delegate filechecking
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and repair to a not-fully-trusted agent.
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The public key is stored on the servers, as is the encrypted salt, the
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(non-encrypted) data salt, the encrypted data, and a signature. The container
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records the write-enabler, but of course this is not visible to readers. To
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make sure that every byte of the share can be verified by a holder of the
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verify-cap (and also by the storage server itself), the signature covers the
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version number, the sequence number, the root hash "R" of the share merkle
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tree, the encoding parameters, and the encrypted salt. "R" itself covers the
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hash trees and the share data.
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The read-write URI is just the private key. The read-only URI is the read-cap
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key. The deep-verify URI is the traversal-cap. The verify-only URI contains
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the the pubkey hash and the first 64 bits of the storage index.
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FMW:b2a(privatekey)
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FMR:b2a(readcap)
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FMT:b2a(traversalcap)
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FMV:b2a(storageindex[:64])b2a(pubkey-hash)
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Note that this allows the read-only, deep-verify, and verify-only URIs to be
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derived from the read-write URI without actually retrieving any data from the
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share, but instead by regenerating the public key from the private one. Users
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of the read-only, deep-verify, or verify-only caps must validate the public
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key against their pubkey hash (or its derivative) the first time they
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retrieve the pubkey, before trusting any signatures they see.
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The SDMF slot is allocated by sending a request to the storage server with a
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desired size, the storage index, and the write enabler for that server's
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nodeid. If granted, the write enabler is stashed inside the slot's backing
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store file. All further write requests must be accompanied by the write
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enabler or they will not be honored. The storage server does not share the
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write enabler with anyone else.
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The SDMF slot structure will be described in more detail below. The important
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pieces are:
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* a sequence number
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* a root hash "R"
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* the data salt
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* the encoding parameters (including k, N, file size, segment size)
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* a signed copy of [seqnum,R,data_salt,encoding_params] (using signature key)
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* the verification key (not encrypted)
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* the share hash chain (part of a Merkle tree over the share hashes)
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* the block hash tree (Merkle tree over blocks of share data)
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* the share data itself (erasure-coding of read-key-encrypted file data)
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* the salt, encrypted with the salt key
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The access pattern for read (assuming we hold the write-cap) is:
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* generate public key from the private one
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* hash private key to get the salt, hash public key, form read-cap
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* form storage-index
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* use storage-index to locate 'k' shares with identical 'R' values
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* either get one share, read 'k' from it, then read k-1 shares
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* or read, say, 5 shares, discover k, either get more or be finished
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* or copy k into the URIs
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* .. jump to "COMMON READ", below
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To read (assuming we only hold the read-cap), do:
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* hash read-cap pieces to generate storage index and salt key
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* use storage-index to locate 'k' shares with identical 'R' values
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* retrieve verification key and encrypted salt
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* decrypt salt
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* hash decrypted salt and pubkey to generate another copy of the read-cap,
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make sure they match (this validates the pubkey)
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* .. jump to "COMMON READ"
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* COMMON READ:
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* read seqnum, R, data salt, encoding parameters, signature
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* verify signature against verification key
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* hash data salt and read-cap to generate read-key
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* read share data, compute block-hash Merkle tree and root "r"
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* read share hash chain (leading from "r" to "R")
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* validate share hash chain up to the root "R"
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* submit share data to erasure decoding
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* decrypt decoded data with read-key
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* submit plaintext to application
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The access pattern for write is:
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* generate pubkey, salt, read-cap, storage-index as in read case
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* generate data salt for this update, generate read-key
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* encrypt plaintext from application with read-key
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* application can encrypt some data with the data-write-key to make it
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only available to writers (used for transitively-readonly dirnodes)
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* erasure-code crypttext to form shares
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* split shares into blocks
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* compute Merkle tree of blocks, giving root "r" for each share
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* compute Merkle tree of shares, find root "R" for the file as a whole
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* create share data structures, one per server:
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* use seqnum which is one higher than the old version
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* share hash chain has log(N) hashes, different for each server
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* signed data is the same for each server
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* include pubkey, encrypted salt, data salt
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* now we have N shares and need homes for them
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* walk through peers
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* if share is not already present, allocate-and-set
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* otherwise, try to modify existing share:
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* send testv_and_writev operation to each one
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* testv says to accept share if their(seqnum+R) <= our(seqnum+R)
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* count how many servers wind up with which versions (histogram over R)
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* keep going until N servers have the same version, or we run out of servers
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* if any servers wound up with a different version, report error to
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application
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* if we ran out of servers, initiate recovery process (described below)
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==== Cryptographic Properties ====
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This scheme protects the data's confidentiality with 192 bits of key
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material, since the read-cap contains 192 secret bits (derived from an
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encrypted salt, which is encrypted using those same 192 bits plus some
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additional public material).
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The integrity of the data (assuming that the signature is valid) is protected
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by the 256-bit hash which gets included in the signature. The privilege of
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modifying the data (equivalent to the ability to form a valid signature) is
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protected by a 256 bit random DSA private key, and the difficulty of
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computing a discrete logarithm in a 2048-bit field.
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There are a few weaker denial-of-service attacks possible. If N-k+1 of the
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shares are damaged or unavailable, the client will be unable to recover the
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file. Any coalition of more than N-k shareholders will be able to effect this
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attack by merely refusing to provide the desired share. The "write enabler"
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shared secret protects existing shares from being displaced by new ones,
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except by the holder of the write-cap. One server cannot affect the other
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shares of the same file, once those other shares are in place.
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The worst DoS attack is the "roadblock attack", which must be made before
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those shares get placed. Storage indexes are effectively random (being
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derived from the hash of a random value), so they are not guessable before
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the writer begins their upload, but there is a window of vulnerability during
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the beginning of the upload, when some servers have heard about the storage
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index but not all of them.
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The roadblock attack we want to prevent is when the first server that the
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uploader contacts quickly runs to all the other selected servers and places a
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bogus share under the same storage index, before the uploader can contact
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them. These shares will normally be accepted, since storage servers create
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new shares on demand. The bogus shares would have randomly-generated
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write-enablers, which will of course be different than the real uploader's
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write-enabler, since the malicious server does not know the write-cap.
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If this attack were successful, the uploader would be unable to place any of
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their shares, because the slots have already been filled by the bogus shares.
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The uploader would probably try for peers further and further away from the
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desired location, but eventually they will hit a preconfigured distance limit
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and give up. In addition, the further the writer searches, the less likely it
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is that a reader will search as far. So a successful attack will either cause
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the file to be uploaded but not be reachable, or it will cause the upload to
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fail.
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If the uploader tries again (creating a new privkey), they may get lucky and
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the malicious servers will appear later in the query list, giving sufficient
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honest servers a chance to see their share before the malicious one manages
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to place bogus ones.
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The first line of defense against this attack is the timing challenges: the
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attacking server must be ready to act the moment a storage request arrives
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(which will only occur for a certain percentage of all new-file uploads), and
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only has a few seconds to act before the other servers will have allocated
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the shares (and recorded the write-enabler, terminating the window of
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vulnerability).
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The second line of defense is post-verification, and is possible because the
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storage index is partially derived from the public key hash. A storage server
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can, at any time, verify every public bit of the container as being signed by
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the verification key (this operation is recommended as a continual background
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process, when disk usage is minimal, to detect disk errors). The server can
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also hash the verification key to derive 64 bits of the storage index. If it
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detects that these 64 bits do not match (but the rest of the share validates
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correctly), then the implication is that this share was stored to the wrong
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storage index, either due to a bug or a roadblock attack.
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If an uploader finds that they are unable to place their shares because of
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"bad write enabler errors" (as reported by the prospective storage servers),
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it can "cry foul", and ask the storage server to perform this verification on
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the share in question. If the pubkey and storage index do not match, the
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storage server can delete the bogus share, thus allowing the real uploader to
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place their share. Of course the origin of the offending bogus share should
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be logged and reported to a central authority, so corrective measures can be
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taken. It may be necessary to have this "cry foul" protocol include the new
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write-enabler, to close the window during which the malicious server can
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re-submit the bogus share during the adjudication process.
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If the problem persists, the servers can be placed into pre-verification
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mode, in which this verification is performed on all potential shares before
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being committed to disk. This mode is more CPU-intensive (since normally the
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storage server ignores the contents of the container altogether), but would
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solve the problem completely.
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The mere existence of these potential defenses should be sufficient to deter
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any actual attacks. Note that the storage index only has 64 bits of
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pubkey-derived data in it, which is below the usual crypto guidelines for
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security factors. In this case it's a pre-image attack which would be needed,
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rather than a collision, and the actual attack would be to find a keypair for
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which the public key can be hashed three times to produce the desired portion
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of the storage index. We believe that 64 bits of material is sufficiently
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resistant to this form of pre-image attack to serve as a suitable deterrent.
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=== SMDF Slot Format ===
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This SMDF data lives inside a server-side MutableSlot container. The server
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is generally oblivious to this format, but it may look inside the container
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when verification is desired.
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This data is tightly packed. There are no gaps left between the different
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fields, and the offset table is mainly present to allow future flexibility of
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key sizes.
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# offset size name
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1 0 1 version byte, \x01 for this format
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2 1 8 sequence number. 2^64-1 must be handled specially, TBD
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3 9 32 "R" (root of share hash Merkle tree)
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4 41 32 data salt (readkey is H(readcap+data_salt))
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5 73 32 encrypted salt (AESenc(key=H(readcap), salt)
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6 105 18 encoding parameters:
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105 1 k
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106 1 N
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107 8 segment size
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115 8 data length (of original plaintext)
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7 123 36 offset table:
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127 4 (9) signature
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131 4 (10) share hash chain
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135 4 (11) block hash tree
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139 4 (12) share data
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143 8 (13) EOF
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8 151 256 verification key (2048bit DSA key)
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9 407 40 signature=DSAsig(H([1,2,3,4,5,6]))
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10 447 (a) share hash chain, encoded as:
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"".join([pack(">H32s", shnum, hash)
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for (shnum,hash) in needed_hashes])
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11 ?? (b) block hash tree, encoded as:
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"".join([pack(">32s",hash) for hash in block_hash_tree])
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12 ?? LEN share data
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13 ?? -- EOF
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(a) The share hash chain contains ceil(log(N)) hashes, each 32 bytes long.
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This is the set of hashes necessary to validate this share's leaf in the
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share Merkle tree. For N=10, this is 4 hashes, i.e. 128 bytes.
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(b) The block hash tree contains ceil(length/segsize) hashes, each 32 bytes
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long. This is the set of hashes necessary to validate any given block of
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share data up to the per-share root "r". Each "r" is a leaf of the share
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has tree (with root "R"), from which a minimal subset of hashes is put in
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the share hash chain in (8).
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== TODO ==
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Every node in a given tahoe grid must have the same common DSA moduli and
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exponent, but different grids could use different parameters. We haven't
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figured out how to define a "grid id" yet, but I think the DSA parameters
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should be part of that identifier. In practical terms, this might mean that
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the Introducer tells each node what parameters to use, or perhaps the node
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could have a config file which specifies them instead.
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The shares MUST have a ciphertext hash of some sort (probably a merkle tree
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over the blocks, and/or a flat hash of the ciphertext), just like immutable
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files do. Without this, a malicious publisher could produce some shares that
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result in file A, and other shares that result in file B, and upload both of
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them (incorporating both into the share hash tree). The result would be a
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read-cap that would sometimes resolve to file A, and sometimes to file B,
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depending upon which servers were used for the download. By including a
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ciphertext hash in the SDMF data structure, the publisher must commit to just
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a single ciphertext, closing this hole. See ticket #492 for more details.
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