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570 lines
23 KiB
ReStructuredText
570 lines
23 KiB
ReStructuredText
.. -*- coding: utf-8 -*-
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Storage Node Protocol ("Great Black Swamp", "GBS")
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==================================================
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The target audience for this document is Tahoe-LAFS developers.
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After reading this document,
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one should expect to understand how Tahoe-LAFS clients interact over the network with Tahoe-LAFS storage nodes.
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The primary goal of the introduction of this protocol is to simplify the task of implementing a Tahoe-LAFS storage server.
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Specifically, it should be possible to implement a Tahoe-LAFS storage server without a Foolscap implementation
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(substituting a simpler GBS server implementation).
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The Tahoe-LAFS client will also need to change but it is not expected that it will be noticably simplified by this change
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(though this may be the first step towards simplifying it).
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Requirements
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------------
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Security
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~~~~~~~~
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Summary
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!!!!!!!
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The storage node protocol should offer at minimum the security properties offered by the Foolscap-based protocol.
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The Foolscap-based protocol offers:
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* **Peer authentication** by way of checked x509 certificates
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* **Message authentication** by way of TLS
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* **Message confidentiality** by way of TLS
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* A careful configuration of the TLS connection parameters *may* also offer **forward secrecy**.
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However, Tahoe-LAFS' use of Foolscap takes no steps to ensure this is the case.
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Discussion
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!!!!!!!!!!
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A client node relies on a storage node to persist certain data until a future retrieval request is made.
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In this way, the client node is vulnerable to attacks which cause the data not to be persisted.
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Though this vulnerability can be (and typically is) mitigated by including redundancy in the share encoding parameters for stored data,
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it is still sensible to attempt to minimize unnecessary vulnerability to this attack.
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One way to do this is for the client to be confident the storage node with which it is communicating is really the expected node.
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That is, for the client to perform **peer authentication** of the storage node it connects to.
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This allows it to develop a notion of that node's reputation over time.
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The more retrieval requests the node satisfies correctly the more it probably will satisfy correctly.
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Therefore, the protocol must include some means for verifying the identify of the storage node.
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The initialization of the client with the correct identity information is out of scope for this protocol
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(the system may be trust-on-first-use, there may be a third-party identity broker, etc).
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With confidence that communication is proceeding with the intended storage node,
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it must also be possible to trust that data is exchanged without modification.
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That is, the protocol must include some means to perform **message authentication**.
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This is most likely done using cryptographic MACs (such as those used in TLS).
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The messages which enable the mutable shares feature include secrets related to those shares.
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For example, the write enabler secret is used to restrict the parties with write access to mutable shares.
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It is exchanged over the network as part of a write operation.
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An attacker learning this secret can overwrite share data with garbage
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(lacking a separate encryption key,
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there is no way to write data which appears legitimate to a legitimate client).
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Therefore, **message confidentiality** is necessary when exchanging these secrets.
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**Forward secrecy** is preferred so that an attacker recording an exchange today cannot launch this attack at some future point after compromising the necessary keys.
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Functionality
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-------------
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Tahoe-LAFS application-level information must be transferred using this protocol.
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This information is exchanged with a dozen or so request/response-oriented messages.
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Some of these messages carry large binary payloads.
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Others are small structured-data messages.
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Some facility for expansion to support new information exchanges should also be present.
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Solutions
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---------
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An HTTP-based protocol, dubbed "Great Black Swamp" (or "GBS"), is described below.
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This protocol aims to satisfy the above requirements at a lower level of complexity than the current Foolscap-based protocol.
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Communication with the storage node will take place using TLS.
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The TLS version and configuration will be dictated by an ongoing understanding of best practices.
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The storage node will present an x509 certificate during the TLS handshake.
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Storage clients will require that the certificate have a valid signature.
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The Subject Public Key Information (SPKI) hash of the certificate will constitute the storage node's identity.
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The **tub id** portion of the storage node fURL will be replaced with the SPKI hash.
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When connecting to a storage node,
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the client will take the following steps to gain confidence it has reached the intended peer:
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* It will perform the usual cryptographic verification of the certificate presented by the storage server.
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That is,
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it will check that the certificate itself is well-formed,
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that it is currently valid [#]_,
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and that the signature it carries is valid.
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* It will compare the SPKI hash of the certificate to the expected value.
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The specifics of the comparison are the same as for the comparison specified by `RFC 7469`_ with "sha256" [#]_.
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To further clarify, consider this example.
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Alice operates a storage node.
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Alice generates a key pair and secures it properly.
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Alice generates a self-signed storage node certificate with the key pair.
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Alice's storage node announces (to an introducer) a fURL containing (among other information) the SPKI hash.
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Imagine the SPKI hash is ``i5xb...``.
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This results in a fURL of ``pb://i5xb...@example.com:443/g3m5...#v=1``.
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Bob creates a client node pointed at the same introducer.
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Bob's client node receives the announcement from Alice's storage node
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(indirected through the introducer).
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Bob's client node recognizes the fURL as referring to an HTTP-dialect server due to the ``v=1`` fragment.
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Bob's client node can now perform a TLS handshake with a server at the address in the fURL location hints
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(``example.com:443`` in this example).
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Following the above described validation procedures,
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Bob's client node can determine whether it has reached Alice's storage node or not.
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If and only if the validation procedure is successful does Bob's client node conclude it has reached Alice's storage node.
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**Peer authentication** has been achieved.
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Additionally,
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by continuing to interact using TLS,
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Bob's client and Alice's storage node are assured of both **message authentication** and **message confidentiality**.
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.. note::
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Foolscap TubIDs are 20 bytes (SHA1 digest of the certificate).
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They are encoded with Base32 for a length of 32 bytes.
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SPKI information discussed here is 32 bytes (SHA256 digest).
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They would be encoded in Base32 for a length of 52 bytes.
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`base64url`_ provides a more compact encoding of the information while remaining URL-compatible.
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This would encode the SPKI information for a length of merely 43 bytes.
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SHA1,
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the current Foolscap hash function,
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is not a practical choice at this time due to advances made in `attacking SHA1`_.
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The selection of a safe hash function with output smaller than SHA256 could be the subject of future improvements.
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A 224 bit hash function (SHA3-224, for example) might be suitable -
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improving the encoded length to 38 bytes.
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Transition
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~~~~~~~~~~
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To provide a seamless user experience during this protocol transition,
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there should be a period during which both protocols are supported by storage nodes.
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The GBS announcement will be introduced in a way that *updated client* software can recognize.
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Its introduction will also be made in such a way that *non-updated client* software disregards the new information
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(of which it cannot make any use).
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Storage nodes will begin to operate a new GBS server.
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They may re-use their existing x509 certificate or generate a new one.
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Generation of a new certificate allows for certain non-optimal conditions to be addressed:
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* The ``commonName`` of ``newpb_thingy`` may be changed to a more descriptive value.
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* A ``notValidAfter`` field with a timestamp in the past may be updated.
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Storage nodes will announce a new fURL for this new HTTP-based server.
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This fURL will be announced alongside their existing Foolscap-based server's fURL.
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Such an announcement will resemble this::
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{
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"anonymous-storage-FURL": "pb://...", # The old key
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"gbs-anonymous-storage-url": "pb://...#v=1" # The new key
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}
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The transition process will proceed in three stages:
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1. The first stage represents the starting conditions in which clients and servers can speak only Foolscap.
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#. The intermediate stage represents a condition in which some clients and servers can both speak Foolscap and GBS.
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#. The final stage represents the desired condition in which all clients and servers speak only GBS.
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During the first stage only one client/server interaction is possible:
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the storage server announces only Foolscap and speaks only Foolscap.
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During the final stage there is only one supported interaction:
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the client and server are both updated and speak GBS to each other.
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During the intermediate stage there are four supported interactions:
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1. Both the client and server are non-updated.
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The interaction is just as it would be during the first stage.
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#. The client is updated and the server is non-updated.
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The client will see the Foolscap announcement and the lack of a GBS announcement.
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It will speak to the server using Foolscap.
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#. The client is non-updated and the server is updated.
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The client will see the Foolscap announcement.
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It will speak Foolscap to the storage server.
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#. Both the client and server are updated.
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The client will see the GBS announcement and disregard the Foolscap announcement.
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It will speak GBS to the server.
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There is one further complication:
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the client maintains a cache of storage server information
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(to avoid continuing to rely on the introducer after it has been introduced).
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The follow sequence of events is likely:
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1. The client connects to an introducer.
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#. It receives an announcement for a non-updated storage server (Foolscap only).
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#. It caches this announcement.
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#. At some point, the storage server is updated.
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#. The client uses the information in its cache to open a Foolscap connection to the storage server.
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Ideally,
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the client would not rely on an update from the introducer to give it the GBS fURL for the updated storage server.
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Therefore,
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when an updated client connects to a storage server using Foolscap,
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it should request the server's version information.
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If this information indicates that GBS is supported then the client should cache this GBS information.
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On subsequent connection attempts,
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it should make use of this GBS information.
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Server Details
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--------------
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The protocol primarily enables interaction with "resources" of two types:
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storage indexes
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and shares.
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A particular resource is addressed by the HTTP request path.
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Details about the interface are encoded in the HTTP message body.
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Message Encoding
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~~~~~~~~~~~~~~~~
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The preferred encoding for HTTP message bodies is `CBOR`_.
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A request may be submitted using an alternate encoding by declaring this in the ``Content-Type`` header.
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A request may indicate its preference for an alternate encoding in the response using the ``Accept`` header.
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These two headers are used in the typical way for an HTTP application.
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The only other encoding support for which is currently recommended is JSON.
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For HTTP messages carrying binary share data,
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this is expected to be a particularly poor encoding.
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However,
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for HTTP messages carrying small payloads of strings, numbers, and containers
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it is expected that JSON will be more convenient than CBOR for ad hoc testing and manual interaction.
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For this same reason,
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JSON is used throughout for the examples presented here.
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Because of the simple types used throughout
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and the equivalence described in `RFC 7049`_
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these examples should be representative regardless of which of these two encodings is chosen.
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General
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~~~~~~~
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``GET /v1/version``
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!!!!!!!!!!!!!!!!!!!
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Retrieve information about the version of the storage server.
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Information is returned as an encoded mapping.
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For example::
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{ "http://allmydata.org/tahoe/protocols/storage/v1" :
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{ "maximum-immutable-share-size": 1234,
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"maximum-mutable-share-size": 1235,
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"available-space": 123456,
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"tolerates-immutable-read-overrun": true,
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"delete-mutable-shares-with-zero-length-writev": true,
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"fills-holes-with-zero-bytes": true,
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"prevents-read-past-end-of-share-data": true,
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"gbs-anonymous-storage-url": "pb://...#v=1"
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},
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"application-version": "1.13.0"
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}
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``PUT /v1/lease/:storage_index``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Create a new lease that applies to all shares for the given storage index.
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The details of the lease are encoded in the request body.
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For example::
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{"renew-secret": "abcd", "cancel-secret": "efgh"}
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If there are no shares for the given ``storage_index``
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then do nothing and return ``NO CONTENT``.
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If the ``renew-secret`` value matches an existing lease
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then that lease will be renewed instead.
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The lease expires after 31 days.
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Discussion
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``````````
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Several behaviors here are blindly copied from the Foolscap-based storage server protocol.
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* There is a cancel secret but there is no API to use it to cancel a lease.
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* The lease period is hard-coded at 31 days.
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* There is no way to differentiate between success and an unknown **storage index**.
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* There are separate **add** and **renew** lease APIs.
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These are not necessarily ideal behaviors
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but they are adopted to avoid any *semantic* changes between the Foolscap- and HTTP-based protocols.
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It is expected that some or all of these behaviors may change in a future revision of the HTTP-based protocol.
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``POST /v1/lease/:storage_index``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Renew an existing lease for all shares for the given storage index.
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The details of the lease are encoded in the request body.
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For example::
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{"renew-secret": "abcd"}
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If there are no shares for the given ``storage_index``
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then ``NOT FOUND`` is returned.
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If there is no lease with a matching ``renew-secret`` value on the given storage index
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then ``NOT FOUND`` is returned.
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In this case,
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if the storage index refers to mutable data
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then the response also includes a list of nodeids where the lease can be renewed.
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For example::
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{"nodeids": ["aaa...", "bbb..."]}
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Othewise,
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the matching lease's expiration time is changed to be 31 days from the time of this operation
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and ``NO CONTENT`` is returned.
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Immutable
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---------
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Writing
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~~~~~~~
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``POST /v1/immutable/:storage_index``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Initialize an immutable storage index with some buckets.
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The buckets may have share data written to them once.
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A lease is also created for the shares.
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Details of the buckets to create are encoded in the request body.
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For example::
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{"renew-secret": "efgh", "cancel-secret": "ijkl",
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"share-numbers": [1, 7, ...], "allocated-size": 12345}
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The response body includes encoded information about the created buckets.
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For example::
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{"already-have": [1, ...], "allocated": [7, ...]}
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Discussion
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``````````
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We considered making this ``POST /v1/immutable`` instead.
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The motivation was to keep *storage index* out of the request URL.
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Request URLs have an elevated chance of being logged by something.
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We were concerned that having the *storage index* logged may increase some risks.
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However, we decided this does not matter because:
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* the *storage index* can only be used to retrieve (not decrypt) the ciphertext-bearing share.
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* the *storage index* is already persistently present on the storage node in the form of directory names in the storage servers ``shares`` directory.
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* the request is made via HTTPS and so only Tahoe-LAFS can see the contents,
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therefore no proxy servers can perform any extra logging.
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* Tahoe-LAFS itself does not currently log HTTP request URLs.
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``PUT /v1/immutable/:storage_index/:share_number``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Write data for the indicated share.
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The share number must belong to the storage index.
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The request body is the raw share data (i.e., ``application/octet-stream``).
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*Content-Range* requests are encouraged for large transfers.
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For example,
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for a 1MiB share the data can be broken in to 8 128KiB chunks.
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Each chunk can be *PUT* separately with the appropriate *Content-Range* header.
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The server must recognize when all of the data has been received and mark the share as complete
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(which it can do because it was informed of the size when the storage index was initialized).
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Clients should upload chunks in re-assembly order.
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Servers may reject out-of-order chunks for implementation simplicity.
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If an individual *PUT* fails then only a limited amount of effort is wasted on the necessary retry.
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.. think about copying https://developers.google.com/drive/api/v2/resumable-upload
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``POST /v1/immutable/:storage_index/:share_number/corrupt``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Advise the server the data read from the indicated share was corrupt.
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The request body includes an human-meaningful string with details about the corruption.
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It also includes potentially important details about the share.
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For example::
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{"reason": "expected hash abcd, got hash efgh"}
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.. share-type, storage-index, and share-number are inferred from the URL
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Reading
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~~~~~~~
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``GET /v1/immutable/:storage_index/shares``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Retrieve a list indicating all shares available for the indicated storage index.
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For example::
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[1, 5]
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``GET /v1/immutable/:storage_index?share=:s0&share=:sN&offset=o1&size=z0&offset=oN&size=zN``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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Read data from the indicated immutable shares.
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If ``share`` query parameters are given, selecte only those shares for reading.
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Otherwise, select all shares present.
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If ``size`` and ``offset`` query parameters are given,
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only the portions thus identified of the selected shares are returned.
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Otherwise, all data is from the selected shares is returned.
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The response body contains a mapping giving the read data.
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For example::
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{
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3: ["foo", "bar"],
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7: ["baz", "quux"]
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}
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Discussion
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``````````
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Offset and size of the requested data are specified here as query arguments.
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Instead, this information could be present in a ``Range`` header in the request.
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This is the more obvious choice and leverages an HTTP feature built for exactly this use-case.
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However, HTTP requires that the ``Content-Type`` of the response to "range requests" be ``multipart/...``.
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The ``multipart`` major type brings along string sentinel delimiting as a means to frame the different response parts.
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There are many drawbacks to this framing technique:
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1. It is resource-intensive to generate.
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2. It is resource-intensive to parse.
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3. It is complex to parse safely [#]_ [#]_ [#]_ [#]_.
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Mutable
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-------
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Writing
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~~~~~~~
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``POST /v1/mutable/:storage_index/read-test-write``
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!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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General purpose read-test-and-write operation for mutable storage indexes.
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A mutable storage index is also called a "slot"
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(particularly by the existing Tahoe-LAFS codebase).
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The first write operation on a mutable storage index creates it
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(that is,
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there is no separate "create this storage index" operation as there is for the immutable storage index type).
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The request body includes the secrets necessary to rewrite to the shares
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along with test, read, and write vectors for the operation.
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For example::
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{
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"secrets": {
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"write-enabler": "abcd",
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"lease-renew": "efgh",
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"lease-cancel": "ijkl"
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},
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"test-write-vectors": {
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0: {
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"test": [{
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"offset": 3,
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"size": 5,
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"operator": "eq",
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"specimen": "hello"
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}, ...],
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"write": [{
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"offset": 9,
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"data": "world"
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}, ...],
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"new-length": 5
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}
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},
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"read-vector": [{"offset": 3, "size": 12}, ...]
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}
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The response body contains a boolean indicating whether the tests all succeed
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(and writes were applied) and a mapping giving read data (pre-write).
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For example::
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{
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"success": true,
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"data": {
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0: ["foo"],
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5: ["bar"],
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...
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}
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}
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Reading
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~~~~~~~
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``GET /v1/mutable/:storage_index/shares``
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|
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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|
|
|
Retrieve a list indicating all shares available for the indicated storage index.
|
|
For example::
|
|
|
|
[1, 5]
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|
|
|
``GET /v1/mutable/:storage_index?share=:s0&share=:sN&offset=:o1&size=:z0&offset=:oN&size=:zN``
|
|
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
|
|
|
|
Read data from the indicated mutable shares.
|
|
Just like ``GET /v1/mutable/:storage_index``.
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|
|
|
``POST /v1/mutable/:storage_index/:share_number/corrupt``
|
|
!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!
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|
|
|
Advise the server the data read from the indicated share was corrupt.
|
|
Just like the immutable version.
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|
|
|
.. _RFC 7469: https://tools.ietf.org/html/rfc7469#section-2.4
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|
|
|
.. _RFC 7049: https://tools.ietf.org/html/rfc7049#section-4
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|
|
|
.. _CBOR: http://cbor.io/
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|
|
|
.. [#]
|
|
The security value of checking ``notValidBefore`` and ``notValidAfter`` is not entirely clear.
|
|
The arguments which apply to web-facing certificates do not seem to apply
|
|
(due to the decision for Tahoe-LAFS to operate independently of the web-oriented CA system).
|
|
|
|
Arguably, complexity is reduced by allowing an existing TLS implementation which wants to make these checks make them
|
|
(compared to including additional code to either bypass them or disregard their results).
|
|
Reducing complexity, at least in general, is often good for security.
|
|
|
|
On the other hand, checking the validity time period forces certificate regeneration
|
|
(which comes with its own set of complexity).
|
|
|
|
A possible compromise is to recommend certificates with validity periods of many years or decades.
|
|
"Recommend" may be read as "provide software supporting the generation of".
|
|
|
|
What about key theft?
|
|
If certificates are valid for years then a successful attacker can pretend to be a valid storage node for years.
|
|
However, short-validity-period certificates are no help in this case.
|
|
The attacker can generate new, valid certificates using the stolen keys.
|
|
|
|
Therefore, the only recourse to key theft
|
|
(really *identity theft*)
|
|
is to burn the identity and generate a new one.
|
|
Burning the identity is a non-trivial task.
|
|
It is worth solving but it is not solved here.
|
|
|
|
.. [#]
|
|
More simply::
|
|
|
|
from hashlib import sha256
|
|
from cryptography.hazmat.primitives.serialization import (
|
|
Encoding,
|
|
PublicFormat,
|
|
)
|
|
from pybase64 import urlsafe_b64encode
|
|
|
|
def check_tub_id(tub_id):
|
|
spki_bytes = cert.public_key().public_bytes(Encoding.DER, PublicFormat.SubjectPublicKeyInfo)
|
|
spki_sha256 = sha256(spki_bytes).digest()
|
|
spki_encoded = urlsafe_b64encode(spki_sha256)
|
|
assert spki_encoded == tub_id
|
|
|
|
Note we use `base64url`_ rather than the Foolscap- and Tahoe-LAFS-preferred Base32.
|
|
|
|
.. [#]
|
|
https://www.cvedetails.com/cve/CVE-2017-5638/
|
|
.. [#]
|
|
https://pivotal.io/security/cve-2018-1272
|
|
.. [#]
|
|
https://nvd.nist.gov/vuln/detail/CVE-2017-5124
|
|
.. [#]
|
|
https://efail.de/
|
|
|
|
.. _base64url: https://tools.ietf.org/html/rfc7515#appendix-C
|
|
|
|
.. _attacking SHA1: https://en.wikipedia.org/wiki/SHA-1#Attacks
|