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Signed-off-by: Daira Hopwood <daira@jacaranda.org>
473 lines
23 KiB
ReStructuredText
473 lines
23 KiB
ReStructuredText
.. -*- coding: utf-8-with-signature -*-
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==========================
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Tahoe-LAFS Directory Nodes
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==========================
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As explained in the architecture docs, Tahoe-LAFS can be roughly viewed as
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a collection of three layers. The lowest layer is the key-value store: it
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provides operations that accept files and upload them to the grid, creating
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a URI in the process which securely references the file's contents.
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The middle layer is the file store, creating a structure of directories and
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filenames resembling the traditional Unix or Windows filesystems. The top
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layer is the application layer, which uses the lower layers to provide useful
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services to users, like a backup application, or a way to share files with
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friends.
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This document examines the middle layer, the "file store".
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1. `Key-value Store Primitives`_
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2. `File Store Goals`_
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3. `Dirnode Goals`_
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4. `Dirnode secret values`_
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5. `Dirnode storage format`_
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6. `Dirnode sizes, mutable-file initial read sizes`_
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7. `Design Goals, redux`_
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1. `Confidentiality leaks in the storage servers`_
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2. `Integrity failures in the storage servers`_
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3. `Improving the efficiency of dirnodes`_
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4. `Dirnode expiration and leases`_
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8. `Starting Points: root dirnodes`_
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9. `Mounting and Sharing Directories`_
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10. `Revocation`_
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Key-value Store Primitives
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==========================
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In the lowest layer (key-value store), there are two operations that reference
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immutable data (which we refer to as "CHK URIs" or "CHK read-capabilities" or
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"CHK read-caps"). One puts data into the grid (but only if it doesn't exist
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already), the other retrieves it::
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chk_uri = put(data)
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data = get(chk_uri)
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We also have three operations which reference mutable data (which we refer to
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as "mutable slots", or "mutable write-caps and read-caps", or sometimes "SSK
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slots"). One creates a slot with some initial contents, a second replaces the
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contents of a pre-existing slot, and the third retrieves the contents::
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mutable_uri = create(initial_data)
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replace(mutable_uri, new_data)
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data = get(mutable_uri)
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File Store Goals
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================
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The main goal for the middle (file store) layer is to give users a way to
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organize the data that they have uploaded into the grid. The traditional way
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to do this in computer filesystems is to put this data into files, give those
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files names, and collect these names into directories.
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Each directory is a set of name-entry pairs, each of which maps a "child name"
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to a directory entry pointing to an object of some kind. Those child objects
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might be files, or they might be other directories. Each directory entry also
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contains metadata.
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The directory structure is therefore a directed graph of nodes, in which each
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node might be a directory node or a file node. All file nodes are terminal
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nodes.
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Dirnode Goals
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=============
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What properties might be desirable for these directory nodes? In no
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particular order:
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1. functional. Code which does not work doesn't count.
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2. easy to document, explain, and understand
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3. confidential: it should not be possible for others to see the contents of
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a directory
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4. integrity: it should not be possible for others to modify the contents
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of a directory
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5. available: directories should survive host failure, just like files do
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6. efficient: in storage, communication bandwidth, number of round-trips
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7. easy to delegate individual directories in a flexible way
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8. updateness: everybody looking at a directory should see the same contents
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9. monotonicity: everybody looking at a directory should see the same
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sequence of updates
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Some of these goals are mutually exclusive. For example, availability and
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consistency are opposing, so it is not possible to achieve #5 and #8 at the
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same time. Moreover, it takes a more complex architecture to get close to the
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available-and-consistent ideal, so #2/#6 is in opposition to #5/#8.
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Tahoe-LAFS v0.7.0 introduced distributed mutable files, which use public-key
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cryptography for integrity, and erasure coding for availability. These
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achieve roughly the same properties as immutable CHK files, but their
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contents can be replaced without changing their identity. Dirnodes are then
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just a special way of interpreting the contents of a specific mutable file.
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Earlier releases used a "vdrive server": this server was abolished in the
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v0.7.0 release.
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For details of how mutable files work, please see :doc:`mutable`.
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For releases since v0.7.0, we achieve most of our desired properties. The
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integrity and availability of dirnodes is equivalent to that of regular
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(immutable) files, with the exception that there are more simultaneous-update
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failure modes for mutable slots. Delegation is quite strong: you can give
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read-write or read-only access to any subtree, and the data format used for
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dirnodes is such that read-only access is transitive: i.e. if you grant Bob
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read-only access to a parent directory, then Bob will get read-only access
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(and *not* read-write access) to its children.
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Relative to the previous "vdrive server"-based scheme, the current
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distributed dirnode approach gives better availability, but cannot guarantee
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updateness quite as well, and requires far more network traffic for each
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retrieval and update. Mutable files are somewhat less available than
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immutable files, simply because of the increased number of combinations
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(shares of an immutable file are either present or not, whereas there are
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multiple versions of each mutable file, and you might have some shares of
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version 1 and other shares of version 2). In extreme cases of simultaneous
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update, mutable files might suffer from non-monotonicity.
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Dirnode secret values
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=====================
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As mentioned before, dirnodes are simply a special way to interpret the
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contents of a mutable file, so the secret keys and capability strings
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described in :doc:`mutable` are all the same. Each dirnode contains an RSA
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public/private keypair, and the holder of the "write capability" will be able
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to retrieve the private key (as well as the AES encryption key used for the
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data itself). The holder of the "read capability" will be able to obtain the
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public key and the AES data key, but not the RSA private key needed to modify
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the data.
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The "write capability" for a dirnode grants read-write access to its
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contents. This is expressed on concrete form as the "dirnode write cap": a
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printable string which contains the necessary secrets to grant this access.
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Likewise, the "read capability" grants read-only access to a dirnode, and can
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be represented by a "dirnode read cap" string.
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For example,
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URI:DIR2:swdi8ge1s7qko45d3ckkyw1aac%3Aar8r5j99a4mezdojejmsfp4fj1zeky9gjigyrid4urxdimego68o
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is a write-capability URI, while
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URI:DIR2-RO:buxjqykt637u61nnmjg7s8zkny:ar8r5j99a4mezdojejmsfp4fj1zeky9gjigyrid4urxdimego68o
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is a read-capability URI, both for the same dirnode.
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Dirnode storage format
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======================
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Each dirnode is stored in a single mutable file, distributed in the Tahoe-LAFS
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grid. The contents of this file are a serialized list of netstrings, one per
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child. Each child is a list of four netstrings: (name, rocap, rwcap,
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metadata). (Remember that the contents of the mutable file are encrypted by
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the read-cap, so this section describes the plaintext contents of the mutable
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file, *after* it has been decrypted by the read-cap.)
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The name is simple a UTF-8 -encoded child name. The 'rocap' is a read-only
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capability URI to that child, either an immutable (CHK) file, a mutable file,
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or a directory. It is also possible to store 'unknown' URIs that are not
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recognized by the current version of Tahoe-LAFS. The 'rwcap' is a read-write
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capability URI for that child, encrypted with the dirnode's write-cap: this
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enables the "transitive readonlyness" property, described further below. The
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'metadata' is a JSON-encoded dictionary of type,value metadata pairs. Some
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metadata keys are pre-defined, the rest are left up to the application.
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Each rwcap is stored as IV + ciphertext + MAC. The IV is a 16-byte random
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value. The ciphertext is obtained by using AES in CTR mode on the rwcap URI
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string, using a key that is formed from a tagged hash of the IV and the
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dirnode's writekey. The MAC is written only for compatibility with older
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Tahoe-LAFS versions and is no longer verified.
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If Bob has read-only access to the 'bar' directory, and he adds it as a child
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to the 'foo' directory, then he will put the read-only cap for 'bar' in both
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the rwcap and rocap slots (encrypting the rwcap contents as described above).
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If he has full read-write access to 'bar', then he will put the read-write
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cap in the 'rwcap' slot, and the read-only cap in the 'rocap' slot. Since
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other users who have read-only access to 'foo' will be unable to decrypt its
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rwcap slot, this limits those users to read-only access to 'bar' as well,
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thus providing the transitive readonlyness that we desire.
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Dirnode sizes, mutable-file initial read sizes
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==============================================
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How big are dirnodes? When reading dirnode data out of mutable files, how
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large should our initial read be? If we guess exactly, we can read a dirnode
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in a single round-trip, and update one in two RTT. If we guess too high,
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we'll waste some amount of bandwidth. If we guess low, we need to make a
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second pass to get the data (or the encrypted privkey, for writes), which
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will cost us at least another RTT.
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Assuming child names are between 10 and 99 characters long, how long are the
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various pieces of a dirnode?
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::
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netstring(name) ~= 4+len(name)
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chk-cap = 97 (for 4-char filesizes)
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dir-rw-cap = 88
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dir-ro-cap = 91
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netstring(cap) = 4+len(cap)
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encrypted(cap) = 16+cap+32
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JSON({}) = 2
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JSON({ctime=float,mtime=float,'tahoe':{linkcrtime=float,linkmotime=float}}): 137
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netstring(metadata) = 4+137 = 141
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so a CHK entry is::
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5+ 4+len(name) + 4+97 + 5+16+97+32 + 4+137
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And a 15-byte filename gives a 416-byte entry. When the entry points at a
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subdirectory instead of a file, the entry is a little bit smaller. So an
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empty directory uses 0 bytes, a directory with one child uses about 416
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bytes, a directory with two children uses about 832, etc.
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When the dirnode data is encoding using our default 3-of-10, that means we
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get 139ish bytes of data in each share per child.
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The pubkey, signature, and hashes form the first 935ish bytes of the
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container, then comes our data, then about 1216 bytes of encprivkey. So if we
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read the first::
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1kB: we get 65bytes of dirnode data : only empty directories
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2kB: 1065bytes: about 8
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3kB: 2065bytes: about 15 entries, or 6 entries plus the encprivkey
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4kB: 3065bytes: about 22 entries, or about 13 plus the encprivkey
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So we've written the code to do an initial read of 4kB from each share when
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we read the mutable file, which should give good performance (one RTT) for
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small directories.
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Design Goals, redux
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===================
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How well does this design meet the goals?
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1. functional: YES: the code works and has extensive unit tests
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2. documentable: YES: this document is the existence proof
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3. confidential: YES: see below
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4. integrity: MOSTLY: a coalition of storage servers can rollback individual
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mutable files, but not a single one. No server can
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substitute fake data as genuine.
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5. availability: YES: as long as 'k' storage servers are present and have
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the same version of the mutable file, the dirnode will
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be available.
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6. efficient: MOSTLY:
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network: single dirnode lookup is very efficient, since clients can
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fetch specific keys rather than being required to get or set
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the entire dirnode each time. Traversing many directories
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takes a lot of roundtrips, and these can't be collapsed with
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promise-pipelining because the intermediate values must only
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be visible to the client. Modifying many dirnodes at once
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(e.g. importing a large pre-existing directory tree) is pretty
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slow, since each graph edge must be created independently.
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storage: each child has a separate IV, which makes them larger than
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if all children were aggregated into a single encrypted string
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7. delegation: VERY: each dirnode is a completely independent object,
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to which clients can be granted separate read-write or
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read-only access
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8. updateness: VERY: with only a single point of access, and no caching,
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each client operation starts by fetching the current
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value, so there are no opportunities for staleness
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9. monotonicity: VERY: the single point of access also protects against
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retrograde motion
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Confidentiality leaks in the storage servers
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--------------------------------------------
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Dirnode (and the mutable files upon which they are based) are very private
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against other clients: traffic between the client and the storage servers is
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protected by the Foolscap SSL connection, so they can observe very little.
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Storage index values are hashes of secrets and thus unguessable, and they are
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not made public, so other clients cannot snoop through encrypted dirnodes
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that they have not been told about.
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Storage servers can observe access patterns and see ciphertext, but they
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cannot see the plaintext (of child names, metadata, or URIs). If an attacker
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operates a significant number of storage servers, they can infer the shape of
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the directory structure by assuming that directories are usually accessed
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from root to leaf in rapid succession. Since filenames are usually much
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shorter than read-caps and write-caps, the attacker can use the length of the
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ciphertext to guess the number of children of each node, and might be able to
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guess the length of the child names (or at least their sum). From this, the
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attacker may be able to build up a graph with the same shape as the plaintext
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file store, but with unlabeled edges and unknown file contents.
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Integrity failures in the storage servers
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-----------------------------------------
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The mutable file's integrity mechanism (RSA signature on the hash of the file
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contents) prevents the storage server from modifying the dirnode's contents
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without detection. Therefore the storage servers can make the dirnode
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unavailable, but not corrupt it.
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A sufficient number of colluding storage servers can perform a rollback
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attack: replace all shares of the whole mutable file with an earlier version.
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To prevent this, when retrieving the contents of a mutable file, the
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client queries more servers than necessary and uses the highest available
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version number. This insures that one or two misbehaving storage servers
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cannot cause this rollback on their own.
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Improving the efficiency of dirnodes
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------------------------------------
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The current mutable-file -based dirnode scheme suffers from certain
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inefficiencies. A very large directory (with thousands or millions of
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children) will take a significant time to extract any single entry, because
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the whole file must be downloaded first, then parsed and searched to find the
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desired child entry. Likewise, modifying a single child will require the
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whole file to be re-uploaded.
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The current design assumes (and in some cases, requires) that dirnodes remain
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small. The mutable files on which dirnodes are based are currently using
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"SDMF" ("Small Distributed Mutable File") design rules, which state that the
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size of the data shall remain below one megabyte. More advanced forms of
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mutable files (MDMF and LDMF) are in the design phase to allow efficient
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manipulation of larger mutable files. This would reduce the work needed to
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modify a single entry in a large directory.
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Judicious caching may help improve the reading-large-directory case. Some
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form of mutable index at the beginning of the dirnode might help as well. The
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MDMF design rules allow for efficient random-access reads from the middle of
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the file, which would give the index something useful to point at.
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The current SDMF design generates a new RSA public/private keypair for each
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directory. This takes considerable time and CPU effort, generally one or two
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seconds per directory. We have designed (but not yet built) a DSA-based
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mutable file scheme which will use shared parameters to reduce the
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directory-creation effort to a bare minimum (picking a random number instead
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of generating two random primes).
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When a backup program is run for the first time, it needs to copy a large
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amount of data from a pre-existing local filesystem into reliable storage.
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This means that a large and complex directory structure needs to be
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duplicated in the dirnode layer. With the one-object-per-dirnode approach
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described here, this requires as many operations as there are edges in the
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imported filesystem graph.
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Another approach would be to aggregate multiple directories into a single
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storage object. This object would contain a serialized graph rather than a
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single name-to-child dictionary. Most directory operations would fetch the
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whole block of data (and presumeably cache it for a while to avoid lots of
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re-fetches), and modification operations would need to replace the whole
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thing at once. This "realm" approach would have the added benefit of
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combining more data into a single encrypted bundle (perhaps hiding the shape
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of the graph from a determined attacker), and would reduce round-trips when
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performing deep directory traversals (assuming the realm was already cached).
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It would also prevent fine-grained rollback attacks from working: a coalition
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of storage servers could change the entire realm to look like an earlier
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state, but it could not independently roll back individual directories.
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The drawbacks of this aggregation would be that small accesses (adding a
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single child, looking up a single child) would require pulling or pushing a
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lot of unrelated data, increasing network overhead (and necessitating
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test-and-set semantics for the modification side, which increases the chances
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that a user operation will fail, making it more challenging to provide
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promises of atomicity to the user).
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It would also make it much more difficult to enable the delegation
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("sharing") of specific directories. Since each aggregate "realm" provides
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all-or-nothing access control, the act of delegating any directory from the
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middle of the realm would require the realm first be split into the upper
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piece that isn't being shared and the lower piece that is. This splitting
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would have to be done in response to what is essentially a read operation,
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which is not traditionally supposed to be a high-effort action. On the other
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hand, it may be possible to aggregate the ciphertext, but use distinct
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encryption keys for each component directory, to get the benefits of both
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schemes at once.
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Dirnode expiration and leases
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-----------------------------
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Dirnodes are created any time a client wishes to add a new directory. How
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long do they live? What's to keep them from sticking around forever, taking
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up space that nobody can reach any longer?
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Mutable files are created with limited-time "leases", which keep the shares
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alive until the last lease has expired or been cancelled. Clients which know
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and care about specific dirnodes can ask to keep them alive for a while, by
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renewing a lease on them (with a typical period of one month). Clients are
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expected to assist in the deletion of dirnodes by canceling their leases as
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soon as they are done with them. This means that when a client unlinks a
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directory, it should also cancel its lease on that directory. When the lease
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count on a given share goes to zero, the storage server can delete the
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related storage. Multiple clients may all have leases on the same dirnode:
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the server may delete the shares only after all of the leases have gone away.
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We expect that clients will periodically create a "manifest": a list of
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so-called "refresh capabilities" for all of the dirnodes and files that they
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can reach. They will give this manifest to the "repairer", which is a service
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that keeps files (and dirnodes) alive on behalf of clients who cannot take on
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this responsibility for themselves. These refresh capabilities include the
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storage index, but do *not* include the readkeys or writekeys, so the
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repairer does not get to read the files or directories that it is helping to
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keep alive.
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After each change to the user's file store, the client creates a manifest and
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looks for differences from their previous version. Anything which was removed
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prompts the client to send out lease-cancellation messages, allowing the data
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to be deleted.
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Starting Points: root dirnodes
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==============================
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Any client can record the URI of a directory node in some external form (say,
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in a local file) and use it as the starting point of later traversal. Each
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Tahoe-LAFS user is expected to create a new (unattached) dirnode when they first
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start using the grid, and record its URI for later use.
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Mounting and Sharing Directories
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================================
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The biggest benefit of this dirnode approach is that sharing individual
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directories is almost trivial. Alice creates a subdirectory that she wants
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to use to share files with Bob. This subdirectory is attached to Alice's
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file store at "alice:shared-with-bob". She asks her file store for the
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read-only directory URI for that new directory, and emails it to Bob. When
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Bob receives the URI, he attaches the given URI into one of his own
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directories, perhaps at a place named "bob:shared-with-alice". Every time
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Alice writes a file into this directory, Bob will be able to read it.
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(It is also possible to share read-write URIs between users, but that makes
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it difficult to follow the `Prime Coordination Directive`_ .) Neither
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Alice nor Bob will get access to any files above the mounted directory:
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there are no 'parent directory' pointers. If Alice creates a nested set of
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directories, "alice:shared-with-bob/subdir2", and gives a read-only URI to
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shared-with-bob to Bob, then Bob will be unable to write to either
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shared-with-bob/ or subdir2/.
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.. _`Prime Coordination Directive`: ../write_coordination.rst
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A suitable UI needs to be created to allow users to easily perform this
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sharing action: dragging a folder from their file store to an IM or email
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user icon, for example. The UI will need to give the sending user an
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opportunity to indicate whether they want to grant read-write or read-only
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access to the recipient. The recipient then needs an interface to drag the
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new folder into their file store and give it a home.
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Revocation
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==========
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When Alice decides that she no longer wants Bob to be able to access the
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shared directory, what should she do? Suppose she's shared this folder with
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both Bob and Carol, and now she wants Carol to retain access to it but Bob to
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be shut out. Ideally Carol should not have to do anything: her access should
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continue unabated.
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The current plan is to have her client create a deep copy of the folder in
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question, delegate access to the new folder to the remaining members of the
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group (Carol), asking the lucky survivors to replace their old reference with
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the new one. Bob may still have access to the old folder, but he is now the
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only one who cares: everyone else has moved on, and he will no longer be able
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to see their new changes. In a strict sense, this is the strongest form of
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revocation that can be accomplished: there is no point trying to force Bob to
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forget about the files that he read a moment before being kicked out. In
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addition it must be noted that anyone who can access the directory can proxy
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for Bob, reading files to him and accepting changes whenever he wants.
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Preventing delegation between communication parties is just as pointless as
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asking Bob to forget previously accessed files. However, there may be value
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to configuring the UI to ask Carol to not share files with Bob, or to
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removing all files from Bob's view at the same time his access is revoked.
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