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.. -*- coding: utf-8-with-signature -*-
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=============================================================
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Redundant Array of Independent Clouds: Share To Cloud Mapping
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=============================================================
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Introduction
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============
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This document describes a proposed design for the mapping of LAFS shares to
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objects in a cloud storage service. It also analyzes the costs for each of the
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functional requirements, including network, disk, storage and API usage costs.
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Terminology
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===========
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*LAFS share*
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A Tahoe-LAFS share representing part of a file after encryption and
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erasure encoding.
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*LAFS shareset*
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The set of shares stored by a LAFS storage server for a given storage index.
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The shares within a shareset are numbered by a small integer.
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*Cloud storage service*
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A service such as Amazon S3 `²`_, Rackspace Cloud Files `³`_,
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Google Cloud Storage `⁴`_, or Windows Azure `⁵`_, that provides cloud storage.
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*Cloud storage interface*
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A protocol interface supported by a cloud storage service, such as the
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S3 interface `⁶`_, the OpenStack Object Storage interface `⁷`_, the
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Google Cloud Storage interface `⁸`_, or the Azure interface `⁹`_. There may be
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multiple services implementing a given cloud storage interface. In this design,
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only REST-based APIs `¹⁰`_ over HTTP will be used as interfaces.
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*Store object*
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A file-like abstraction provided by a cloud storage service, storing a
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sequence of bytes. Store objects are mutable in the sense that the contents
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and metadata of the store object with a given name in a given backend store
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can be replaced. Store objects are called “blobs” in the Azure interface,
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and “objects” in the other interfaces.
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*Cloud backend store*
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A container for store objects provided by a cloud service. Cloud backend
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stores are called “buckets” in the S3 and Google Cloud Storage interfaces,
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and “containers” in the Azure and OpenStack Storage interfaces.
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Functional Requirements
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=======================
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* *Upload*: a LAFS share can be uploaded to an appropriately configured
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Tahoe-LAFS storage server and the data is stored to the cloud
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storage service.
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* *Scalable shares*: there is no hard limit on the size of LAFS share
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that can be uploaded.
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If the cloud storage interface offers scalable files, then this could be
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implemented by using that feature of the specific cloud storage
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interface. Alternately, it could be implemented by mapping from the LAFS
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abstraction of an unlimited-size immutable share to a set of size-limited
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store objects.
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* *Streaming upload*: the size of the LAFS share that is uploaded
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can exceed the amount of RAM and even the amount of direct attached
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storage on the storage server. I.e., the storage server is required to
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stream the data directly to the ultimate cloud storage service while
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processing it, instead of to buffer the data until the client is finished
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uploading and then transfer the data to the cloud storage service.
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* *Download*: a LAFS share can be downloaded from an appropriately
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configured Tahoe-LAFS storage server, and the data is loaded from the
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cloud storage service.
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* *Streaming download*: the size of the LAFS share that is
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downloaded can exceed the amount of RAM and even the amount of direct
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attached storage on the storage server. I.e. the storage server is
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required to stream the data directly to the client while processing it,
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instead of to buffer the data until the cloud storage service is finished
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serving and then transfer the data to the client.
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* *Modify*: a LAFS share can have part of its contents modified.
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If the cloud storage interface offers scalable mutable files, then this
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could be implemented by using that feature of the specific cloud storage
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interface. Alternately, it could be implemented by mapping from the LAFS
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abstraction of an unlimited-size mutable share to a set of size-limited
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store objects.
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* *Efficient modify*: the size of the LAFS share being
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modified can exceed the amount of RAM and even the amount of direct
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attached storage on the storage server. I.e. the storage server is
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required to download, patch, and upload only the segment(s) of the share
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that are being modified, instead of to download, patch, and upload the
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entire share.
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* *Tracking leases*: The Tahoe-LAFS storage server is required to track when
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each share has its lease renewed so that unused shares (shares whose lease
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has not been renewed within a time limit, e.g. 30 days) can be garbage
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collected. This does not necessarily require code specific to each cloud
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storage interface, because the lease tracking can be performed in the
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storage server's generic component rather than in the component supporting
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each interface.
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Mapping
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=======
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This section describes the mapping between LAFS shares and store objects.
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A LAFS share will be split into one or more “chunks” that are each stored in a
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store object. A LAFS share of size `C` bytes will be stored as `ceiling(C / chunksize)`
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chunks. The last chunk has a size between 1 and `chunksize` bytes inclusive.
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(It is not possible for `C` to be zero, because valid shares always have a header,
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so, there is at least one chunk for each share.)
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For an existing share, the chunk size is determined by the size of the first
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chunk. For a new share, it is a parameter that may depend on the storage
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interface. It is an error for any chunk to be larger than the first chunk, or
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for any chunk other than the last to be smaller than the first chunk.
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If a mutable share with total size less than the default chunk size for the
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storage interface is being modified, the new contents are split using the
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default chunk size.
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*Rationale*: this design allows the `chunksize` parameter to be changed for
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new shares written via a particular storage interface, without breaking
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compatibility with existing stored shares. All cloud storage interfaces
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return the sizes of store objects with requests to list objects, and so
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the size of the first chunk can be determined without an additional request.
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The name of the store object for chunk `i` > 0 of a LAFS share with storage index
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`STORAGEINDEX` and share number `SHNUM`, will be
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shares/`ST`/`STORAGEINDEX`/`SHNUM.i`
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where `ST` is the first two characters of `STORAGEINDEX`. When `i` is 0, the
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`.0` is omitted.
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*Rationale*: this layout maintains compatibility with data stored by the
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prototype S3 backend, for which Least Authority Enterprises has existing
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customers. This prototype always used a single store object to store each
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share, with name
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shares/`ST`/`STORAGEINDEX`/`SHNUM`
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By using the same prefix “shares/`ST`/`STORAGEINDEX`/” for old and new layouts,
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the storage server can obtain a list of store objects associated with a given
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shareset without having to know the layout in advance, and without having to
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make multiple API requests. This also simplifies sharing of test code between the
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disk and cloud backends.
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Mutable and immutable shares will be “chunked” in the same way.
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Rationale for Chunking
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----------------------
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Limiting the amount of data received or sent in a single request has the
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following advantages:
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* It is unnecessary to write separate code to take advantage of the
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“large object” features of each cloud storage interface, which differ
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significantly in their design.
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* Data needed for each PUT request can be discarded after it completes.
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If a PUT request fails, it can be retried while only holding the data
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for that request in memory.
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Costs
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=====
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In this section we analyze the costs of the proposed design in terms of network,
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disk, memory, cloud storage, and API usage.
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Network usage—bandwidth and number-of-round-trips
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-------------------------------------------------
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When a Tahoe-LAFS storage client allocates a new share on a storage server,
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the backend will request a list of the existing store objects with the
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appropriate prefix. This takes one HTTP request in the common case, but may
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take more for the S3 interface, which has a limit of 1000 objects returned in
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a single “GET Bucket” request.
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If the share is to be read, the client will make a number of calls each
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specifying the offset and length of the required span of bytes. On the first
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request that overlaps a given chunk of the share, the server will make an
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HTTP GET request for that store object. The server may also speculatively
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make GET requests for store objects that are likely to be needed soon (which
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can be predicted since reads are normally sequential), in order to reduce
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latency.
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Each read will be satisfied as soon as the corresponding data is available,
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without waiting for the rest of the chunk, in order to minimize read latency.
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All four cloud storage interfaces support GET requests using the
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Range HTTP header. This could be used to optimize reads where the
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Tahoe-LAFS storage client requires only part of a share.
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If the share is to be written, the server will make an HTTP PUT request for
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each chunk that has been completed. Tahoe-LAFS clients only write immutable
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shares sequentially, and so we can rely on that property to simplify the
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implementation.
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When modifying shares of an existing mutable file, the storage server will
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be able to make PUT requests only for chunks that have changed.
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(Current Tahoe-LAFS v1.9 clients will not take advantage of this ability, but
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future versions will probably do so for MDMF files.)
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In some cases, it may be necessary to retry a request (see the `Structure of
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Implementation`_ section below). In the case of a PUT request, at the point
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at which a retry is needed, the new chunk contents to be stored will still be
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in memory and so this is not problematic.
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In the absence of retries, the maximum number of GET requests that will be made
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when downloading a file, or the maximum number of PUT requests when uploading
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or modifying a file, will be equal to the number of chunks in the file.
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If the new mutable share content has fewer chunks than the old content,
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then the remaining store objects for old chunks must be deleted (using one
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HTTP request each). When reading a share, the backend must tolerate the case
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where these store objects have not been deleted successfully.
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The last write to a share will be reported as successful only when all
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corresponding HTTP PUTs and DELETEs have completed successfully.
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Disk usage (local to the storage server)
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----------------------------------------
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It is never necessary for the storage server to write the content of share
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chunks to local disk, either when they are read or when they are written. Each
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chunk is held only in memory.
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A proposed change to the Tahoe-LAFS storage server implementation uses a sqlite
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database to store metadata about shares. In that case the same database would
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be used for the cloud backend. This would enable lease tracking to be implemented
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in the same way for disk and cloud backends.
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Memory usage
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------------
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The use of chunking simplifies bounding the memory usage of the storage server
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when handling files that may be larger than memory. However, this depends on
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limiting the number of chunks that are simultaneously held in memory.
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Multiple chunks can be held in memory either because of pipelining of requests
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for a single share, or because multiple shares are being read or written
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(possibly by multiple clients).
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For immutable shares, the Tahoe-LAFS storage protocol requires the client to
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specify in advance the maximum amount of data it will write. Also, a cooperative
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client (including all existing released versions of the Tahoe-LAFS code) will
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limit the amount of data that is pipelined, currently to 50 KiB. Since the chunk
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size will be greater than that, it is possible to ensure that for each allocation,
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the maximum chunk data memory usage is the lesser of two chunks, and the allocation
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size. (There is some additional overhead but it is small compared to the chunk
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data.) If the maximum memory usage of a new allocation would exceed the memory
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available, the allocation can be delayed or possibly denied, so that the total
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memory usage is bounded.
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It is not clear that the existing protocol allows allocations for mutable
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shares to be bounded in general; this may be addressed in a future protocol change.
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The above discussion assumes that clients do not maliciously send large
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messages as a denial-of-service attack. Foolscap (the protocol layer underlying
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the Tahoe-LAFS storage protocol) does not attempt to resist denial of service.
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Storage
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-------
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The storage requirements, including not-yet-collected garbage shares, are
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the same as for the Tahoe-LAFS disk backend. That is, the total size of cloud
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objects stored is equal to the total size of shares that the disk backend
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would store.
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Erasure coding causes the size of shares for each file to be a
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factor `shares.total` / `shares.needed` times the file size, plus overhead
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that is logarithmic in the file size `¹¹`_.
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API usage
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---------
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Cloud storage backends typically charge a small fee per API request. The number of
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requests to the cloud storage service for various operations is discussed under
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“network usage” above.
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Structure of Implementation
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===========================
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A generic “cloud backend”, based on the prototype S3 backend but with support
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for chunking as described above, will be written.
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An instance of the cloud backend can be attached to one of several
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“cloud interface adapters”, one for each cloud storage interface. These
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adapters will operate only on chunks, and need not distinguish between
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mutable and immutable shares. They will be a relatively “thin” abstraction
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layer over the HTTP APIs of each cloud storage interface, similar to the
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S3Bucket abstraction in the prototype.
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For some cloud storage services it may be necessary to transparently retry
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requests in order to recover from transient failures. (Although the erasure
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coding may enable a file to be retrieved even when shares are not stored by or
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not readable from all cloud storage services used in a Tahoe-LAFS grid, it may
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be desirable to retry cloud storage service requests in order to improve overall
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reliability.) Support for this will be implemented in the generic cloud backend,
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and used whenever a cloud storage adaptor reports a transient failure. Our
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experience with the prototype suggests that it is necessary to retry on transient
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failures for Amazon's S3 service.
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There will also be a “mock” cloud interface adaptor, based on the prototype's
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MockS3Bucket. This allows tests of the generic cloud backend to be run without
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a connection to a real cloud service. The mock adaptor will be able to simulate
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transient and non-transient failures.
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Known Issues
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============
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This design worsens a known “write hole” issue in Tahoe-LAFS when updating
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the contents of mutable files. An update to a mutable file can require
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changing the contents of multiple chunks, and if the client fails or is
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disconnected during the operation the resulting state of the store objects
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for that share may be inconsistent—no longer containing all of the old version,
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but not yet containing all of the new version. A mutable share can be left in
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an inconsistent state even by the existing Tahoe-LAFS disk backend if it fails
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during a write, but that has a smaller chance of occurrence because the current
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client behavior leads to mutable shares being written to disk in a single
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system call.
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2012-06-06 02:35:23 +00:00
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The best fix for this issue probably requires changing the Tahoe-LAFS storage
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protocol, perhaps by extending it to use a two-phase or three-phase commit
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(ticket #1755).
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References
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===========
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¹ omitted
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.. _²:
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² “Amazon S3” Amazon (2012)
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https://aws.amazon.com/s3/
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.. _³:
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³ “Rackspace Cloud Files” Rackspace (2012)
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https://www.rackspace.com/cloud/cloud_hosting_products/files/
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.. _⁴:
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⁴ “Google Cloud Storage” Google (2012)
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https://developers.google.com/storage/
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.. _⁵:
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⁵ “Windows Azure Storage” Microsoft (2012)
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https://www.windowsazure.com/en-us/develop/net/fundamentals/cloud-storage/
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.. _⁶:
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⁶ “Amazon Simple Storage Service (Amazon S3) API Reference: REST API” Amazon (2012)
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http://docs.amazonwebservices.com/AmazonS3/latest/API/APIRest.html
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.. _⁷:
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⁷ “OpenStack Object Storage” openstack.org (2012)
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http://openstack.org/projects/storage/
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.. _⁸:
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⁸ “Google Cloud Storage Reference Guide” Google (2012)
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https://developers.google.com/storage/docs/reference-guide
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.. _⁹:
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⁹ “Windows Azure Storage Services REST API Reference” Microsoft (2012)
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http://msdn.microsoft.com/en-us/library/windowsazure/dd179355.aspx
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.. _¹⁰:
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¹⁰ “Representational state transfer” English Wikipedia (2012)
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https://en.wikipedia.org/wiki/Representational_state_transfer
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.. _¹¹:
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¹¹ “Performance costs for some common operations” tahoe-lafs.org (2012)
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2016-12-12 21:48:13 +00:00
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:doc:`../../performance`
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