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211 lines
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211 lines
11 KiB
Plaintext
= Specification Document Outline =
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While we do not yet have a clear set of specification documents for Tahoe
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(explaining the file formats, so that others can write interoperable
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implementations), this document is intended to lay out an outline for what
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these specs ought to contain. Think of this as the ISO 7-Layer Model for
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Tahoe.
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We currently imagine 4 documents.
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== #1: Share Format, Encoding Algorithm ==
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This document will describe the way that files are encrypted and encoded into
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shares. It will include a specification of the share format, and explain both
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the encoding and decoding algorithms. It will cover both mutable and
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immutable files.
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The immutable encoding algorithm, as described by this document, will start
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with a plaintext series of bytes, encoding parameters "k" and "N", and either
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an encryption key or a mechanism for deterministically deriving the key from
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the plaintext (the CHK specification). The algorithm will end with a set of N
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shares, and a set of values that must be included in the filecap to provide
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confidentiality (the encryption key) and integrity (the UEB hash).
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The immutable decoding algorithm will start with the filecap values (key and
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UEB hash) and "k" shares. It will explain how to validate the shares against
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the integrity information, how to reverse the erasure-coding, and how to
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decrypt the resulting ciphertext. It will result in the original plaintext
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bytes (or some subrange thereof).
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The sections on mutable files will contain similar information.
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This document is *not* responsible for explaining the filecap format, since
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full filecaps may need to contain additional information as described in
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document #3. Likewise it it not responsible for explaining where to put the
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generated shares or where to find them again later.
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It is also not responsible for explaining the access control mechanisms
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surrounding share upload, download, or modification ("Accounting" is the
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business of controlling share upload to conserve space, and mutable file
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shares require some sort of access control to prevent non-writecap holders
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from destroying shares). We don't yet have a document dedicated to explaining
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these, but let's call it "Access Control" for now.
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== #2: Share Exchange Protocol ==
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This document explains the wire-protocol used to upload, download, and modify
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shares on the various storage servers.
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Given the N shares created by the algorithm described in document #1, and a
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set of servers who are willing to accept those shares, the protocols in this
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document will be sufficient to get the shares onto the servers. Likewise,
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given a set of servers who hold at least k shares, these protocols will be
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enough to retrieve the shares necessary to begin the decoding process
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described in document #1. The notion of a "storage index" is used to
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reference a particular share: the storage index is generated by the encoding
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process described in document #1.
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This document does *not* describe how to identify or choose those servers,
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rather it explains what to do once they have been selected (by the mechanisms
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in document #3).
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This document also explains the protocols that a client uses to ask a server
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whether or not it is willing to accept an uploaded share, and whether it has
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a share available for download. These protocols will be used by the
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mechanisms in document #3 to help decide where the shares should be placed.
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Where cryptographic mechanisms are necessary to implement access-control
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policy, this document will explain those mechanisms.
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In the future, Tahoe will be able to use multiple protocols to speak to
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storage servers. There will be alternative forms of this document, one for
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each protocol. The first one to be written will describe the Foolscap-based
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protocol that tahoe currently uses, but we anticipate a subsequent one to
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describe a more HTTP-based protocol.
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== #3: Server Selection Algorithm, filecap format ==
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This document has two interrelated purposes. With a deeper understanding of
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the issues, we may be able to separate these more cleanly in the future.
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The first purpose is to explain the server selection algorithm. Given a set
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of N shares, where should those shares be uploaded? Given some information
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stored about a previously-uploaded file, how should a downloader locate and
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recover at least k shares? Given a previously-uploaded mutable file, how
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should a modifier locate all (or most of) the shares with a reasonable amount
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of work?
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This question implies many things, all of which should be explained in this
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document:
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* the notion of a "grid", nominally a set of servers who could potentially
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hold shares, which might change over time
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* a way to configure which grid should be used
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* a way to discover which servers are a part of that grid
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* a way to decide which servers are reliable enough to be worth sending
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shares
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* an algorithm to handle servers which refuse shares
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* a way for a downloader to locate which servers have shares
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* a way to choose which shares should be used for download
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The server-selection algorithm has several obviously competing goals:
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* minimize the amount of work that must be done during upload
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* minimize the total storage resources used
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* avoid "hot spots", balance load among multiple servers
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* maximize the chance that enough shares will be downloadable later, by
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uploading lots of shares, and by placing them on reliable servers
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* minimize the work that the future downloader must do
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* tolerate temporary server failures, permanent server departure, and new
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server insertions
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* minimize the amount of information that must be added to the filecap
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The server-selection algorithm is defined in some context: some set of
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expectations about the servers or grid with which it is expected to operate.
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Different algorithms are appropriate for different situtations, so there will
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be multiple alternatives of this document.
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The first version of this document will describe the algorithm that the
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current (1.3.0) release uses, which is heavily weighted towards the two main
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use case scenarios for which Tahoe has been designed: the small, stable
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friendnet, and the allmydata.com managed grid. In both cases, we assume that
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the storage servers are online most of the time, they are uniformly highly
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reliable, and that the set of servers does not change very rapidly. The
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server-selection algorithm for this environment uses a permuted server list
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to achieve load-balancing, uses all servers identically, and derives the
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permutation key from the storage index to avoid adding a new field to the
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filecap.
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An alternative algorithm could give clients more precise control over share
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placement, for example by a user who wished to make sure that k+1 shares are
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located in each datacenter (to allow downloads to take place using only local
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bandwidth). This algorithm could skip the permuted list and use other
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mechanisms to accomplish load-balancing (or ignore the issue altogether). It
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could add additional information to the filecap (like a list of which servers
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received the shares) in lieu of performing a search at download time, perhaps
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at the expense of allowing a repairer to move shares to a new server after
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the initial upload. It might make up for this by storing "location hints"
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next to each share, to indicate where other shares are likely to be found,
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and obligating the repairer to update these hints.
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The second purpose of this document is to explain the format of the file
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capability string (or "filecap" for short). There are multiple kinds of
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capabilties (read-write, read-only, verify-only, repaircap, lease-renewal
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cap, traverse-only, etc). There are multiple ways to represent the filecap
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(compressed binary, human-readable, clickable-HTTP-URL, "tahoe:" URL, etc),
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but they must all contain enough information to reliably retrieve a file
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(given some context, of course). It must at least contain the confidentiality
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and integrity information from document #1 (i.e. the encryption key and the
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UEB hash). It must also contain whatever additional information the
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upload-time server-selection algorithm generated that will be required by the
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downloader.
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For some server-selection algorithms, the additional information will be
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minimal. For example, the 1.3.0 release uses the hash of the encryption key
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as a storage index, and uses the storage index to permute the server list,
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and uses an Introducer to learn the current list of servers. This allows a
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"close-enough" list of servers to be compressed into a filecap field that is
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already required anyways (the encryption key). It also adds k and N to the
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filecap, to speed up the downloader's search (the downloader knows how many
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shares it needs, so it can send out multiple queries in parallel).
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But other server-selection algorithms might require more information. Each
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variant of this document will explain how to encode that additional
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information into the filecap, and how to extract and use that information at
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download time.
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These two purposes are interrelated. A filecap that is interpreted in the
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context of the allmydata.com commercial grid, which uses tahoe-1.3.0, implies
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a specific peer-selection algorithm, a specific Introducer, and therefore a
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fairly-specific set of servers to query for shares. A filecap which is meant
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to be interpreted on a different sort of grid would need different
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information.
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Some filecap formats can be designed to contain more information (and depend
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less upon context), such as the way an HTTP URL implies the existence of a
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single global DNS system. Ideally a tahoe filecap should be able to specify
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which "grid" it lives in, with enough information to allow a compatible
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implementation of Tahoe to locate that grid and retrieve the file (regardless
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of which server-selection algorithm was used for upload).
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This more-universal format might come at the expense of reliability, however.
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Tahoe-1.3.0 filecaps do not contain hostnames, because the failure of DNS or
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an individual host might then impact file availability (however the
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Introducer contains DNS names or IP addresses).
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== #4: Directory Format ==
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Tahoe directories are a special way of interpreting and managing the contents
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of a file (either mutable or immutable). These "dirnode" files are basically
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serialized tables that map child name to filecap/dircap. This document
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describes the format of these files.
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Tahoe-1.3.0 directories are "transitively readonly", which is accomplished by
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applying an additional layer of encryption to the list of child writecaps.
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The key for this encryption is derived from the containing file's writecap.
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This document must explain how to derive this key and apply it to the
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appropriate portion of the table.
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Future versions of the directory format are expected to contain
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"deep-traversal caps", which allow verification/repair of files without
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exposing their plaintext to the repair agent. This document wil be
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responsible for explaining traversal caps too.
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Future versions of the directory format will probably contain an index and
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more advanced data structures (for efficiency and fast lookups), instead of a
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simple flat list of (childname, childcap). This document will also need to
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describe metadata formats, including what access-control policies are defined
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for the metadata.
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