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Signed-off-by: Daira Hopwood <daira@jacaranda.org>
208 lines
8.9 KiB
ReStructuredText
208 lines
8.9 KiB
ReStructuredText
.. -*- coding: utf-8-with-signature -*-
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==========
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Tahoe URIs
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==========
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1. `File URIs`_
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1. `CHK URIs`_
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2. `LIT URIs`_
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3. `Mutable File URIs`_
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2. `Directory URIs`_
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3. `Internal Usage of URIs`_
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Each file and directory in a Tahoe-LAFS file store is described by a "URI".
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There are different kinds of URIs for different kinds of objects, and there
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are different kinds of URIs to provide different kinds of access to those
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objects. Each URI is a string representation of a "capability" or "cap", and
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there are read-caps, write-caps, verify-caps, and others.
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Each URI provides both ``location`` and ``identification`` properties.
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``location`` means that holding the URI is sufficient to locate the data it
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represents (this means it contains a storage index or a lookup key, whatever
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is necessary to find the place or places where the data is being kept).
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``identification`` means that the URI also serves to validate the data: an
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attacker who wants to trick you into into using the wrong data will be
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limited in their abilities by the identification properties of the URI.
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Some URIs are subsets of others. In particular, if you know a URI which
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allows you to modify some object, you can produce a weaker read-only URI and
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give it to someone else, and they will be able to read that object but not
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modify it. Directories, for example, have a read-cap which is derived from
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the write-cap: anyone with read/write access to the directory can produce a
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limited URI that grants read-only access, but not the other way around.
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src/allmydata/uri.py is the main place where URIs are processed. It is
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the authoritative definition point for all the the URI types described
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herein.
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File URIs
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=========
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The lowest layer of the Tahoe architecture (the "key-value store") is
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reponsible for mapping URIs to data. This is basically a distributed
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hash table, in which the URI is the key, and some sequence of bytes is
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the value.
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There are two kinds of entries in this table: immutable and mutable. For
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immutable entries, the URI represents a fixed chunk of data. The URI itself
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is derived from the data when it is uploaded into the grid, and can be used
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to locate and download that data from the grid at some time in the future.
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For mutable entries, the URI identifies a "slot" or "container", which can be
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filled with different pieces of data at different times.
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It is important to note that the values referenced by these URIs are just
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sequences of bytes, and that **no** filenames or other metadata is retained at
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this layer. The file store layer (which sits above the key-value store layer)
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is entirely responsible for directories and filenames and the like.
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CHK URIs
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--------
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CHK (Content Hash Keyed) files are immutable sequences of bytes. They are
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uploaded in a distributed fashion using a "storage index" (for the "location"
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property), and encrypted using a "read key". A secure hash of the data is
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computed to help validate the data afterwards (providing the "identification"
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property). All of these pieces, plus information about the file's size and
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the number of shares into which it has been distributed, are put into the
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"CHK" uri. The storage index is derived by hashing the read key (using a
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tagged SHA-256d hash, then truncated to 128 bits), so it does not need to be
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physically present in the URI.
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The current format for CHK URIs is the concatenation of the following
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strings::
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URI:CHK:(key):(hash):(needed-shares):(total-shares):(size)
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Where (key) is the base32 encoding of the 16-byte AES read key, (hash) is the
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base32 encoding of the SHA-256 hash of the URI Extension Block,
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(needed-shares) is an ascii decimal representation of the number of shares
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required to reconstruct this file, (total-shares) is the same representation
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of the total number of shares created, and (size) is an ascii decimal
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representation of the size of the data represented by this URI. All base32
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encodings are expressed in lower-case, with the trailing '=' signs removed.
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For example, the following is a CHK URI, generated from a previous version of
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the contents of :doc:`architecture.rst<../architecture>`::
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URI:CHK:ihrbeov7lbvoduupd4qblysj7a:bg5agsdt62jb34hxvxmdsbza6do64f4fg5anxxod2buttbo6udzq:3:10:28733
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Historical note: The name "CHK" is somewhat inaccurate and continues to be
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used for historical reasons. "Content Hash Key" means that the encryption key
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is derived by hashing the contents, which gives the useful property that
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encoding the same file twice will result in the same URI. However, this is an
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optional step: by passing a different flag to the appropriate API call, Tahoe
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will generate a random encryption key instead of hashing the file: this gives
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the useful property that the URI or storage index does not reveal anything
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about the file's contents (except filesize), which improves privacy. The
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URI:CHK: prefix really indicates that an immutable file is in use, without
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saying anything about how the key was derived.
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LIT URIs
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--------
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LITeral files are also an immutable sequence of bytes, but they are so short
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that the data is stored inside the URI itself. These are used for files of 55
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bytes or shorter, which is the point at which the LIT URI is the same length
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as a CHK URI would be.
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LIT URIs do not require an upload or download phase, as their data is stored
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directly in the URI.
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The format of a LIT URI is simply a fixed prefix concatenated with the base32
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encoding of the file's data::
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URI:LIT:bjuw4y3movsgkidbnrwg26lemf2gcl3xmvrc6kropbuhi3lmbi
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The LIT URI for an empty file is "URI:LIT:", and the LIT URI for a 5-byte
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file that contains the string "hello" is "URI:LIT:nbswy3dp".
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Mutable File URIs
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-----------------
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The other kind of DHT entry is the "mutable slot", in which the URI names a
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container to which data can be placed and retrieved without changing the
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identity of the container.
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These slots have write-caps (which allow read/write access), read-caps (which
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only allow read-access), and verify-caps (which allow a file checker/repairer
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to confirm that the contents exist, but does not let it decrypt the
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contents).
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Mutable slots use public key technology to provide data integrity, and put a
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hash of the public key in the URI. As a result, the data validation is
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limited to confirming that the data retrieved matches *some* data that was
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uploaded in the past, but not _which_ version of that data.
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The format of the write-cap for mutable files is::
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URI:SSK:(writekey):(fingerprint)
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Where (writekey) is the base32 encoding of the 16-byte AES encryption key
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that is used to encrypt the RSA private key, and (fingerprint) is the base32
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encoded 32-byte SHA-256 hash of the RSA public key. For more details about
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the way these keys are used, please see :doc:`mutable`.
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The format for mutable read-caps is::
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URI:SSK-RO:(readkey):(fingerprint)
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The read-cap is just like the write-cap except it contains the other AES
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encryption key: the one used for encrypting the mutable file's contents. This
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second key is derived by hashing the writekey, which allows the holder of a
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write-cap to produce a read-cap, but not the other way around. The
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fingerprint is the same in both caps.
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Historical note: the "SSK" prefix is a perhaps-inaccurate reference to
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"Sub-Space Keys" from the Freenet project, which uses a vaguely similar
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structure to provide mutable file access.
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Directory URIs
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==============
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The key-value store layer provides a mapping from URI to data. To turn this
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into a graph of directories and files, the "file store" layer (which sits on
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top of the key-value store layer) needs to keep track of "directory nodes",
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or "dirnodes" for short. :doc:`dirnodes` describes how these work.
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Dirnodes are contained inside mutable files, and are thus simply a particular
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way to interpret the contents of these files. As a result, a directory
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write-cap looks a lot like a mutable-file write-cap::
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URI:DIR2:(writekey):(fingerprint)
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Likewise directory read-caps (which provide read-only access to the
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directory) look much like mutable-file read-caps::
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URI:DIR2-RO:(readkey):(fingerprint)
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Historical note: the "DIR2" prefix is used because the non-distributed
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dirnodes in earlier Tahoe releases had already claimed the "DIR" prefix.
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Internal Usage of URIs
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======================
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The classes in source:src/allmydata/uri.py are used to pack and unpack these
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various kinds of URIs. Three Interfaces are defined (IURI, IFileURI, and
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IDirnodeURI) which are implemented by these classes, and string-to-URI-class
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conversion routines have been registered as adapters, so that code which
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wants to extract e.g. the size of a CHK or LIT uri can do::
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print IFileURI(uri).get_size()
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If the URI does not represent a CHK or LIT uri (for example, if it was for a
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directory instead), the adaptation will fail, raising a TypeError inside the
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IFileURI() call.
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Several utility methods are provided on these objects. The most important is
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``to_string()``, which returns the string form of the URI. Therefore
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``IURI(uri).to_string == uri`` is true for any valid URI. See the IURI class
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in source:src/allmydata/interfaces.py for more details.
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