From: Daira Hopwood Date: Mon, 1 Dec 2014 21:48:28 +0000 (+0000) Subject: LAFS now stands for "Least-Authority File Store" rather than "Least-Authority File... X-Git-Url: https://git.rkrishnan.org/?a=commitdiff_plain;h=48b4f772a6dc002b5bc289f543b162f09e6ba901;p=tahoe-lafs%2Ftahoe-lafs.git LAFS now stands for "Least-Authority File Store" rather than "Least-Authority File System". refs #2345 Signed-off-by: Daira Hopwood --- diff --git a/README.rst b/README.rst index 6ab4e285..2e33839b 100644 --- a/README.rst +++ b/README.rst @@ -2,10 +2,10 @@ Tahoe-LAFS ========== -Tahoe-LAFS is a Free Software/Open Source decentralized data store. It -distributes your filesystem across multiple servers, and even if some of the -servers fail or are taken over by an attacker, the entire filesystem continues -to work correctly and to preserve your privacy and security. +Tahoe-LAFS is a Free and Open decentralized cloud storage system. It distributes your +data across multiple servers. Even if some of the servers fail or are taken over by an +attacker, the entire file store continues to function correctly, preserving your privacy +and security. To get started please see `quickstart.rst`_ in the docs directory. diff --git a/docs/about.rst b/docs/about.rst index 6df61229..74a16eeb 100644 --- a/docs/about.rst +++ b/docs/about.rst @@ -45,7 +45,7 @@ Here's how it works: A "storage grid" is made up of a number of storage servers. A storage server has direct attached storage (typically one or more hard disks). A "gateway" communicates with storage nodes, and uses them to provide access to the -filesystem over protocols such as HTTP(S), SFTP or FTP. +grid over protocols such as HTTP(S), SFTP or FTP. Note that you can find "client" used to refer to gateway nodes (which act as a client to storage servers), and also to processes or programs connecting to @@ -72,8 +72,8 @@ An alternate deployment mode is that the gateway runs on a remote machine and the user connects to it over HTTPS or SFTP. This means that the operator of the gateway can view and modify the user's data (the user *relies on* the gateway for confidentiality and integrity), but the advantage is that the -user can access the filesystem with a client that doesn't have the gateway -software installed, such as an Internet kiosk or cell phone. +user can access the Tahoe-LAFS grid with a client that doesn't have the +gateway software installed, such as an Internet kiosk or cell phone. Access Control ============== diff --git a/docs/architecture.rst b/docs/architecture.rst index 68bab0f3..75026a76 100644 --- a/docs/architecture.rst +++ b/docs/architecture.rst @@ -10,7 +10,7 @@ Tahoe-LAFS Architecture 4. `Capabilities`_ 5. `Server Selection`_ 6. `Swarming Download, Trickling Upload`_ -7. `The Filesystem Layer`_ +7. `The File Store Layer`_ 8. `Leases, Refreshing, Garbage Collection`_ 9. `File Repairer`_ 10. `Security`_ @@ -22,7 +22,7 @@ Overview (See the `docs/specifications directory`_ for more details.) -There are three layers: the key-value store, the filesystem, and the +There are three layers: the key-value store, the file store, and the application. The lowest layer is the key-value store. The keys are "capabilities" -- short @@ -33,19 +33,19 @@ values, but there may be performance issues with extremely large values (just due to the limitation of network bandwidth). In practice, values as small as a few bytes and as large as tens of gigabytes are in common use. -The middle layer is the decentralized filesystem: a directed graph in which +The middle layer is the decentralized file store: a directed graph in which the intermediate nodes are directories and the leaf nodes are files. The leaf nodes contain only the data -- they contain no metadata other than the length in bytes. The edges leading to leaf nodes have metadata attached to them about the file they point to. Therefore, the same file may be associated with different metadata if it is referred to through different edges. -The top layer consists of the applications using the filesystem. +The top layer consists of the applications using the file store. Allmydata.com used it for a backup service: the application periodically -copies files from the local disk onto the decentralized filesystem. We later +copies files from the local disk onto the decentralized file store. We later provide read-only access to those files, allowing users to recover them. There are several other applications built on top of the Tahoe-LAFS -filesystem (see the RelatedProjects_ page of the wiki for a list). +file store (see the RelatedProjects_ page of the wiki for a list). .. _docs/specifications directory: specifications .. _RelatedProjects: https://tahoe-lafs.org/trac/tahoe-lafs/wiki/RelatedProjects @@ -157,7 +157,7 @@ The "key-value store" layer doesn't include human-meaningful names. Capabilities sit on the "global+secure" edge of `Zooko's Triangle`_. They are self-authenticating, meaning that nobody can trick you into accepting a file that doesn't match the capability you used to refer to that file. The -filesystem layer (described below) adds human-meaningful names atop the +file store layer (described below) adds human-meaningful names atop the key-value layer. .. _`Zooko's Triangle`: https://en.wikipedia.org/wiki/Zooko%27s_triangle @@ -321,15 +321,15 @@ See helper.rst_ for details about the upload helper. .. _helper.rst: helper.rst -The Filesystem Layer +The File Store Layer ==================== -The "filesystem" layer is responsible for mapping human-meaningful pathnames +The "file store" layer is responsible for mapping human-meaningful pathnames (directories and filenames) to pieces of data. The actual bytes inside these -files are referenced by capability, but the filesystem layer is where the +files are referenced by capability, but the file store layer is where the directory names, file names, and metadata are kept. -The filesystem layer is a graph of directories. Each directory contains a +The file store layer is a graph of directories. Each directory contains a table of named children. These children are either other directories or files. All children are referenced by their capability. @@ -355,11 +355,11 @@ that are globally visible. Leases, Refreshing, Garbage Collection ====================================== -When a file or directory in the virtual filesystem is no longer referenced, -the space that its shares occupied on each storage server can be freed, -making room for other shares. Tahoe-LAFS uses a garbage collection ("GC") -mechanism to implement this space-reclamation process. Each share has one or -more "leases", which are managed by clients who want the file/directory to be +When a file or directory in the file store is no longer referenced, the space +that its shares occupied on each storage server can be freed, making room for +other shares. Tahoe-LAFS uses a garbage collection ("GC") mechanism to +implement this space-reclamation process. Each share has one or more +"leases", which are managed by clients who want the file/directory to be retained. The storage server accepts each share for a pre-defined period of time, and is allowed to delete the share if all of the leases are cancelled or allowed to expire. @@ -383,7 +383,7 @@ Shares may go away because the storage server hosting them has suffered a failure: either temporary downtime (affecting availability of the file), or a permanent data loss (affecting the preservation of the file). Hard drives crash, power supplies explode, coffee spills, and asteroids strike. The goal -of a robust distributed filesystem is to survive these setbacks. +of a robust distributed file store is to survive these setbacks. To work against this slow, continual loss of shares, a File Checker is used to periodically count the number of shares still available for any given diff --git a/docs/configuration.rst b/docs/configuration.rst index 26d8c58b..70524e20 100644 --- a/docs/configuration.rst +++ b/docs/configuration.rst @@ -389,10 +389,10 @@ Client Configuration Frontend Configuration ====================== -The Tahoe client process can run a variety of frontend file-access protocols. -You will use these to create and retrieve files from the virtual filesystem. -Configuration details for each are documented in the following -protocol-specific guides: +The Tahoe-LAFS client process can run a variety of frontend file access +protocols. You will use these to create and retrieve files from the +Tahoe-LAFS file store. Configuration details for each are documented in +the following protocol-specific guides: HTTP @@ -408,7 +408,7 @@ HTTP CLI The main "bin/tahoe" executable includes subcommands for manipulating the - filesystem, uploading/downloading files, and creating/running Tahoe + file store, uploading/downloading files, and creating/running Tahoe-LAFS nodes. See CLI.rst_ for details. SFTP, FTP diff --git a/docs/frontends/CLI.rst b/docs/frontends/CLI.rst index e91632f5..a50e54d5 100644 --- a/docs/frontends/CLI.rst +++ b/docs/frontends/CLI.rst @@ -10,7 +10,7 @@ The Tahoe-LAFS CLI commands 1. `Unicode Support`_ 3. `Node Management`_ -4. `Filesystem Manipulation`_ +4. `File Store Manipulation`_ 1. `Starting Directories`_ 2. `Command Syntax Summary`_ @@ -24,7 +24,7 @@ Overview ======== Tahoe-LAFS provides a single executable named "``tahoe``", which can be used to -create and manage client/server nodes, manipulate the filesystem, and perform +create and manage client/server nodes, manipulate the file store, and perform several debugging/maintenance tasks. This executable lives in the source tree at "``bin/tahoe``". Once you've done a @@ -46,7 +46,7 @@ CLI Command Overview The "``tahoe``" tool provides access to three categories of commands. * node management: create a client/server node, start/stop/restart it -* filesystem manipulation: list files, upload, download, unlink, rename +* file store manipulation: list files, upload, download, unlink, rename * debugging: unpack cap-strings, examine share files To get a list of all commands, just run "``tahoe``" with no additional @@ -139,15 +139,15 @@ is most often used by developers who have just modified the code and want to start using their changes. -Filesystem Manipulation +File Store Manipulation ======================= -These commands let you exmaine a Tahoe-LAFS filesystem, providing basic +These commands let you exmaine a Tahoe-LAFS file store, providing basic list/upload/download/unlink/rename/mkdir functionality. They can be used as primitives by other scripts. Most of these commands are fairly thin wrappers around web-API calls, which are described in ``__. -By default, all filesystem-manipulation commands look in ``~/.tahoe/`` to +By default, all file store manipulation commands look in ``~/.tahoe/`` to figure out which Tahoe-LAFS node they should use. When the CLI command makes web-API calls, it will use ``~/.tahoe/node.url`` for this purpose: a running Tahoe-LAFS node that provides a web-API port will write its URL into this @@ -162,7 +162,7 @@ Starting Directories -------------------- As described in `docs/architecture.rst <../architecture.rst>`__, the -Tahoe-LAFS distributed filesystem consists of a collection of directories +Tahoe-LAFS distributed file store consists of a collection of directories and files, each of which has a "read-cap" or a "write-cap" (also known as a URI). Each directory is simply a table that maps a name to a child file or directory, and this table is turned into a string and stored in a @@ -353,7 +353,7 @@ Command Examples ``tahoe ls subdir`` - This lists a subdirectory of your filesystem. + This lists a subdirectory of your file store. ``tahoe webopen`` diff --git a/docs/frontends/FTP-and-SFTP.rst b/docs/frontends/FTP-and-SFTP.rst index 4d174d59..8358cdec 100644 --- a/docs/frontends/FTP-and-SFTP.rst +++ b/docs/frontends/FTP-and-SFTP.rst @@ -42,8 +42,8 @@ Tahoe-LAFS Support All Tahoe-LAFS client nodes can run a frontend SFTP server, allowing regular SFTP clients (like ``/usr/bin/sftp``, the ``sshfs`` FUSE plugin, and many -others) to access the virtual filesystem. They can also run an FTP server, -so FTP clients (like ``/usr/bin/ftp``, ``ncftp``, and others) can too. These +others) to access the file store. They can also run an FTP server, so FTP +clients (like ``/usr/bin/ftp``, ``ncftp``, and others) can too. These frontends sit at the same level as the web-API interface. Since Tahoe-LAFS does not use user accounts or passwords, the SFTP/FTP diff --git a/docs/frontends/webapi.rst b/docs/frontends/webapi.rst index 0968f39b..8637c31c 100644 --- a/docs/frontends/webapi.rst +++ b/docs/frontends/webapi.rst @@ -71,8 +71,8 @@ port 3456, on the loopback (127.0.0.1) interface. Basic Concepts: GET, PUT, DELETE, POST ====================================== -As described in `docs/architecture.rst`_, each file and directory in a Tahoe -virtual filesystem is referenced by an identifier that combines the +As described in `docs/architecture.rst`_, each file and directory in a +Tahoe-LAFS file store is referenced by an identifier that combines the designation of the object with the authority to do something with it (such as read or modify the contents). This identifier is called a "read-cap" or "write-cap", depending upon whether it enables read-only or read-write @@ -93,7 +93,7 @@ Other variations (generally implemented by adding query parameters to the URL) will return information about the object, such as metadata. GET operations are required to have no side-effects. -PUT is used to upload new objects into the filesystem, or to replace an +PUT is used to upload new objects into the file store, or to replace an existing link or the contents of a mutable file. DELETE is used to unlink objects from directories. Both PUT and DELETE are required to be idempotent: performing the same operation multiple times must have the same side-effects @@ -107,12 +107,12 @@ unlinking), because otherwise a regular web browser has no way to accomplish these tasks. In general, everything that can be done with a PUT or DELETE can also be done with a POST. -Tahoe's web API is designed for two different kinds of consumer. The first is -a program that needs to manipulate the virtual file system. Such programs are +Tahoe-LAFS' web API is designed for two different kinds of consumer. The +first is a program that needs to manipulate the file store. Such programs are expected to use the RESTful interface described above. The second is a human -using a standard web browser to work with the filesystem. This user is given -a series of HTML pages with links to download files, and forms that use POST -actions to upload, rename, and unlink files. +using a standard web browser to work with the file store. This user is +presented with a series of HTML pages with links to download files, and forms +that use POST actions to upload, rename, and unlink files. When an error occurs, the HTTP response code will be set to an appropriate 400-series code (like 404 Not Found for an unknown childname, or 400 Bad Request @@ -333,7 +333,7 @@ Programmatic Operations ======================= Now that we know how to build URLs that refer to files and directories in a -Tahoe virtual filesystem, what sorts of operations can we do with those URLs? +Tahoe-LAFS file store, what sorts of operations can we do with those URLs? This section contains a catalog of GET, PUT, DELETE, and POST operations that can be performed on these URLs. This set of operations are aimed at programs that use HTTP to communicate with a Tahoe node. A later section describes @@ -412,7 +412,7 @@ Writing/Uploading a File ``PUT /uri`` This uploads a file, and produces a file-cap for the contents, but does not - attach the file into the filesystem. No directories will be modified by + attach the file into the file store. No directories will be modified by this operation. The file-cap is returned as the body of the HTTP response. This method accepts format= and mutable=true as query string arguments, and @@ -428,7 +428,7 @@ Creating a New Directory Create a new empty directory and return its write-cap as the HTTP response body. This does not make the newly created directory visible from the - filesystem. The "PUT" operation is provided for backwards compatibility: + file store. The "PUT" operation is provided for backwards compatibility: new code should use POST. This supports a format= argument in the query string. The format= @@ -802,8 +802,8 @@ child is set. The value of the 'tahoe':'linkcrtime' key is updated whenever a link to a child is created -- i.e. when there was not previously a link under that name. -Note however, that if the edge in the Tahoe filesystem points to a mutable -file and the contents of that mutable file is changed, then the +Note however, that if the edge in the Tahoe-LAFS file store points to a +mutable file and the contents of that mutable file is changed, then the 'tahoe':'linkmotime' value on that edge will *not* be updated, since the edge itself wasn't updated -- only the mutable file was. @@ -830,8 +830,8 @@ The reason we added the new fields in Tahoe v1.4.0 is that there is a values of the 'mtime'/'ctime' pair, and this API is used by the "tahoe backup" command (in Tahoe v1.3.0 and later) to set the 'mtime' and 'ctime' values when backing up files from a local filesystem into the -Tahoe filesystem. As of Tahoe v1.4.0, the set_children API cannot be used -to set anything under the 'tahoe' key of the metadata dict -- if you +Tahoe-LAFS file store. As of Tahoe v1.4.0, the set_children API cannot be +used to set anything under the 'tahoe' key of the metadata dict -- if you include 'tahoe' keys in your 'metadata' arguments then it will silently ignore those keys. @@ -859,8 +859,8 @@ When an edge is created or updated by "tahoe backup", the 'mtime' and There are several ways that the 'ctime' field could be confusing: 1. You might be confused about whether it reflects the time of the creation - of a link in the Tahoe filesystem (by a version of Tahoe < v1.7.0) or a - timestamp copied in by "tahoe backup" from a local filesystem. + of a link in the Tahoe-LAFS file store (by a version of Tahoe < v1.7.0) + or a timestamp copied in by "tahoe backup" from a local filesystem. 2. You might be confused about whether it is a copy of the file creation time (if "tahoe backup" was run on a Windows system) or of the last @@ -890,7 +890,7 @@ Attaching an Existing File or Directory by its read- or write-cap ``PUT /uri/$DIRCAP/[SUBDIRS../]CHILDNAME?t=uri`` This attaches a child object (either a file or directory) to a specified - location in the virtual filesystem. The child object is referenced by its + location in the Tahoe-LAFS file store. The child object is referenced by its read- or write- cap, as provided in the HTTP request body. This will create intermediate directories as necessary. @@ -1003,9 +1003,9 @@ Browser Operations: Human-oriented interfaces This section describes the HTTP operations that provide support for humans running a web browser. Most of these operations use HTML forms that use POST -to drive the Tahoe node. This section is intended for HTML authors who want -to write web pages that contain forms and buttons which manipulate the Tahoe -filesystem. +to drive the Tahoe-LAFS node. This section is intended for HTML authors who +want to write web pages containing user interfaces for manipulating the +Tahoe-LAFS file store. Note that for all POST operations, the arguments listed can be provided either as URL query arguments or as form body fields. URL query arguments are @@ -1100,8 +1100,8 @@ Creating a Directory ``POST /uri?t=mkdir`` - This creates a new empty directory, but does not attach it to the virtual - filesystem. + This creates a new empty directory, but does not attach it to any other + directory in the Tahoe-LAFS file store. If a "redirect_to_result=true" argument is provided, then the HTTP response will cause the web browser to be redirected to a /uri/$DIRCAP page that @@ -1143,8 +1143,8 @@ Uploading a File ``POST /uri?t=upload`` This uploads a file, and produces a file-cap for the contents, but does not - attach the file into the filesystem. No directories will be modified by - this operation. + attach the file to any directory in the Tahoe-LAFS file store. That is, no + directories will be modified by this operation. The file must be provided as the "file" field of an HTML encoded form body, produced in response to an HTML form like this:: @@ -1693,7 +1693,7 @@ field, but that has been removed since it was computed incorrectly. for debugging. This is a table of (path, filecap/dircap), for every object reachable from the starting directory. The path will be slash-joined, and the filecap/dircap will contain a link to the object in question. This page - gives immediate access to every object in the virtual filesystem subtree. + gives immediate access to every object in the file store subtree. This operation uses the same ophandle= mechanism as deep-check. The corresponding /operations/$HANDLE page has three different forms. The @@ -1824,9 +1824,9 @@ Other Useful Pages ================== The portion of the web namespace that begins with "/uri" (and "/named") is -dedicated to giving users (both humans and programs) access to the Tahoe -virtual filesystem. The rest of the namespace provides status information -about the state of the Tahoe node. +dedicated to giving users (both humans and programs) access to the Tahoe-LAFS +file store. The rest of the namespace provides status information about the +state of the Tahoe-LAFS node. ``GET /`` (the root page) @@ -1834,11 +1834,11 @@ This is the "Welcome Page", and contains a few distinct sections:: Node information: library versions, local nodeid, services being provided. - Filesystem Access Forms: create a new directory, view a file/directory by + File store access forms: create a new directory, view a file/directory by URI, upload a file (unlinked), download a file by URI. - Grid Status: introducer information, helper information, connected storage + Grid status: introducer information, helper information, connected storage servers. ``GET /status/`` @@ -1985,9 +1985,9 @@ Safety and Security Issues -- Names vs. URIs ============================================ Summary: use explicit file- and dir- caps whenever possible, to reduce the -potential for surprises when the filesystem structure is changed. +potential for surprises when the file store structure is changed. -Tahoe provides a mutable filesystem, but the ways that the filesystem can +Tahoe-LAFS provides a mutable file store, but the ways that the store can change are limited. The only thing that can change is that the mapping from child names to child objects that each directory contains can be changed by adding a new child name pointing to an object, removing an existing child name, diff --git a/docs/garbage-collection.rst b/docs/garbage-collection.rst index ad61d231..bfd26c5d 100644 --- a/docs/garbage-collection.rst +++ b/docs/garbage-collection.rst @@ -13,7 +13,7 @@ Garbage Collection in Tahoe Overview ======== -When a file or directory in the virtual filesystem is no longer referenced, +When a file or directory in a Tahoe-LAFS file store is no longer referenced, the space that its shares occupied on each storage server can be freed, making room for other shares. Tahoe currently uses a garbage collection ("GC") mechanism to implement this space-reclamation process. Each share has diff --git a/docs/man/tahoe.1 b/docs/man/tahoe.1 index 09ef35b6..ca77709e 100644 --- a/docs/man/tahoe.1 +++ b/docs/man/tahoe.1 @@ -1,7 +1,7 @@ .TH TAHOE 1 "July 2011" "Tahoe-LAFS \[em] tahoe command" "User Commands" .SH NAME .PP -tahoe - Secure distributed filesystem. +tahoe - Secure distributed file store. .SH SYNOPSIS .PP tahoe \f[I]COMMAND\f[] [\f[I]OPTION\f[]]... [\f[I]PARAMETER\f[]]... @@ -133,7 +133,7 @@ other than \f[B]run\f[]: `$HOME/.tahoe/'). Display help and exit .RS .RE -.SS USING THE FILESYSTEM +.SS USING THE FILE STORE .TP .B \f[B]mkdir\f[] Create a new directory. diff --git a/docs/proposed/README.lossmodel b/docs/proposed/README.lossmodel index 068affd7..1a87ea1e 100644 --- a/docs/proposed/README.lossmodel +++ b/docs/proposed/README.lossmodel @@ -1,6 +1,6 @@ The lossmodel.lyx file is the source document for an in-progress paper -that analyzes the probability of losing files stored in a Tahoe -Least-acces File System under various scenarios. It describes: +that analyzes the probability of losing files stored in a Tahoe-LAFS +file store under various scenarios. It describes: 1. How to estimate peer reliabilities, based on peer MTBF failure data. diff --git a/docs/quickstart.rst b/docs/quickstart.rst index e0395062..b16923b6 100644 --- a/docs/quickstart.rst +++ b/docs/quickstart.rst @@ -71,6 +71,6 @@ its self-tests. Run Tahoe-LAFS -------------- -Now you are ready to deploy a decentralized filesystem. The ``tahoe`` +Now you are ready to deploy a decentralized file store. The ``tahoe`` executable in the ``bin`` directory can configure and launch your Tahoe-LAFS nodes. See ``__ for instructions on how to do that. diff --git a/docs/running.rst b/docs/running.rst index d5770ce5..a61c6648 100644 --- a/docs/running.rst +++ b/docs/running.rst @@ -102,10 +102,10 @@ The CLI Prefer the command-line? Run “``tahoe --help``” (the same command-line tool that is used to start and stop nodes serves to navigate and use the -decentralized filesystem). To get started, create a new directory and mark it +decentralized file store). To get started, create a new directory and mark it as the 'tahoe:' alias by running “``tahoe create-alias tahoe``”. Once you've done that, you can do “``tahoe ls tahoe:``” and “``tahoe cp LOCALFILE -tahoe:foo.txt``” to work with your filesystem. The Tahoe-LAFS CLI uses +tahoe:foo.txt``” to work with your file store. The Tahoe-LAFS CLI uses similar syntax to the well-known scp and rsync tools. See CLI.rst_ for more details. diff --git a/docs/specifications/dirnodes.rst b/docs/specifications/dirnodes.rst index 9741be38..24c7690f 100644 --- a/docs/specifications/dirnodes.rst +++ b/docs/specifications/dirnodes.rst @@ -8,17 +8,17 @@ As explained in the architecture docs, Tahoe-LAFS can be roughly viewed as a collection of three layers. The lowest layer is the key-value store: it provides operations that accept files and upload them to the grid, creating a URI in the process which securely references the file's contents. -The middle layer is the filesystem, creating a structure of directories and -filenames resembling the traditional unix/windows filesystems. The top layer -is the application layer, which uses the lower layers to provide useful +The middle layer is the file store, creating a structure of directories and +filenames resembling the traditional Unix or Windows filesystems. The top +layer is the application layer, which uses the lower layers to provide useful services to users, like a backup application, or a way to share files with friends. -This document examines the middle layer, the "filesystem". +This document examines the middle layer, the "file store". 1. `Key-value Store Primitives`_ -2. `Filesystem goals`_ -3. `Dirnode goals`_ +2. `File Store Goals`_ +3. `Dirnode Goals`_ 4. `Dirnode secret values`_ 5. `Dirnode storage format`_ 6. `Dirnode sizes, mutable-file initial read sizes`_ @@ -53,10 +53,10 @@ contents of a pre-existing slot, and the third retrieves the contents:: replace(mutable_uri, new_data) data = get(mutable_uri) -Filesystem Goals +File Store Goals ================ -The main goal for the middle (filesystem) layer is to give users a way to +The main goal for the middle (file store) layer is to give users a way to organize the data that they have uploaded into the grid. The traditional way to do this in computer filesystems is to put this data into files, give those files names, and collect these names into directories. @@ -292,7 +292,7 @@ shorter than read-caps and write-caps, the attacker can use the length of the ciphertext to guess the number of children of each node, and might be able to guess the length of the child names (or at least their sum). From this, the attacker may be able to build up a graph with the same shape as the plaintext -filesystem, but with unlabeled edges and unknown file contents. +file store, but with unlabeled edges and unknown file contents. Integrity failures in the storage servers @@ -342,11 +342,11 @@ directory-creation effort to a bare minimum (picking a random number instead of generating two random primes). When a backup program is run for the first time, it needs to copy a large -amount of data from a pre-existing filesystem into reliable storage. This -means that a large and complex directory structure needs to be duplicated in -the dirnode layer. With the one-object-per-dirnode approach described here, -this requires as many operations as there are edges in the imported -filesystem graph. +amount of data from a pre-existing local filesystem into reliable storage. +This means that a large and complex directory structure needs to be +duplicated in the dirnode layer. With the one-object-per-dirnode approach +described here, this requires as many operations as there are edges in the +imported filesystem graph. Another approach would be to aggregate multiple directories into a single storage object. This object would contain a serialized graph rather than a @@ -445,7 +445,7 @@ sharing action: dragging a folder their vdrive to an IM or email user icon, for example. The UI will need to give the sending user an opportunity to indicate whether they want to grant read-write or read-only access to the recipient. The recipient then needs an interface to drag the new folder into -their vdrive and give it a home. +their file store and give it a home. Revocation ========== diff --git a/docs/specifications/uri.rst b/docs/specifications/uri.rst index 9e6d2336..f6efc6e8 100644 --- a/docs/specifications/uri.rst +++ b/docs/specifications/uri.rst @@ -13,9 +13,9 @@ Tahoe URIs 2. `Directory URIs`_ 3. `Internal Usage of URIs`_ -Each file and directory in a Tahoe filesystem is described by a "URI". There -are different kinds of URIs for different kinds of objects, and there are -different kinds of URIs to provide different kinds of access to those +Each file and directory in a Tahoe-LAFS file store is described by a "URI". +There are different kinds of URIs for different kinds of objects, and there +are different kinds of URIs to provide different kinds of access to those objects. Each URI is a string representation of a "capability" or "cap", and there are read-caps, write-caps, verify-caps, and others. diff --git a/docs/write_coordination.rst b/docs/write_coordination.rst index 4c0d319d..2ad024d4 100644 --- a/docs/write_coordination.rst +++ b/docs/write_coordination.rst @@ -14,7 +14,7 @@ directory at a time. One convenient way to accomplish this is to make a different file or directory for each person or process that wants to write. -If mutable parts of a filesystem are accessed via sshfs, only a single +If mutable parts of a file store are accessed via sshfs, only a single sshfs mount should be used. There may be data loss if mutable files or directories are accessed via two sshfs mounts, or written both via sshfs and from other clients. diff --git a/relnotes.txt b/relnotes.txt index 5ae94e62..fe054456 100644 --- a/relnotes.txt +++ b/relnotes.txt @@ -1,4 +1,4 @@ -ANNOUNCING Tahoe, the Least-Authority File System, v1.10 +ANNOUNCING Tahoe, the Least-Authority File Store, v1.10 The Tahoe-LAFS team is pleased to announce the immediate availability of version 1.10.0 of Tahoe-LAFS, an extremely @@ -26,9 +26,9 @@ details. WHAT IS IT GOOD FOR? -With Tahoe-LAFS, you distribute your filesystem across +With Tahoe-LAFS, you distribute your file store across multiple servers, and even if some of the servers fail or are -taken over by an attacker, the entire filesystem continues to +taken over by an attacker, the entire file store continues to work correctly, and continues to preserve your privacy and security. You can easily share specific files and directories with other people. diff --git a/setup.py b/setup.py index 0693e634..caa574a1 100644 --- a/setup.py +++ b/setup.py @@ -438,7 +438,7 @@ if version: setup_args["version"] = version setup(name=APPNAME, - description='secure, decentralized, fault-tolerant filesystem', + description='secure, decentralized, fault-tolerant file store', long_description=open('README.rst', 'rU').read(), author='the Tahoe-LAFS project', author_email='tahoe-dev@tahoe-lafs.org', diff --git a/src/allmydata/scripts/runner.py b/src/allmydata/scripts/runner.py index 08596707..df4c5f5a 100644 --- a/src/allmydata/scripts/runner.py +++ b/src/allmydata/scripts/runner.py @@ -43,7 +43,7 @@ class Options(usage.Options): + startstop_node.subCommands + GROUP("Debugging") + debug.subCommands - + GROUP("Using the filesystem") + + GROUP("Using the file store") + cli.subCommands )