tahoe-lafs/docs/configuration.rst
Brian Warner 0a89b738bc Make introducer.furl unguessable. Closes #1802.
Previously, Introducers always used a swissnum of "introducer", so
anyone who could learn the (public) tubid of the introducer would be
able to connect to and use it. This changes new Introducers to use the
same randomly-generated swissnum as clients and storage servers do, so
that you absolutely must learn the introducer.furl from someone who
knows it already before you can connect.

This change also moves the location of the file that stores
introducer.furl from BASEDIR/introducer.furl to
BASEDIR/private/introducer.furl, since that's where we keep the private
things. The first time an introducer is started with the new code, it
will move any existing BASEDIR/introducer.furl into the new place.

Note that this will not change the FURL of existing introducers: it will
only affect newly created ones. When you change an introducer's FURL,
you must also update all of the nodes (clients and storage servers)
which connect to it, so upgrading it to an unguessable one isn't
something we should do automatically.
2013-03-20 22:40:33 +00:00

695 lines
28 KiB
ReStructuredText

=============================
Configuring a Tahoe-LAFS node
=============================
1. `Node Types`_
2. `Overall Node Configuration`_
3. `Client Configuration`_
4. `Storage Server Configuration`_
5. `Frontend Configuration`_
6. `Running A Helper`_
7. `Running An Introducer`_
8. `Other Files in BASEDIR`_
9. `Other files`_
10. `Example`_
A Tahoe-LAFS node is configured by writing to files in its base directory.
These files are read by the node when it starts, so each time you change
them, you need to restart the node.
The node also writes state to its base directory, so it will create files on
its own.
This document contains a complete list of the config files that are examined
by the client node, as well as the state files that you'll observe in its
base directory.
The main file is named "``tahoe.cfg``", and is an ".INI"-style configuration
file (parsed by the Python stdlib 'ConfigParser' module: "``[name]``" section
markers, lines with "``key.subkey: value``", rfc822-style
continuations). There are also other files containing information that does
not easily fit into this format. The "``tahoe create-node``" or "``tahoe
create-client``" command will create an initial ``tahoe.cfg`` file for
you. After creation, the node will never modify the ``tahoe.cfg`` file: all
persistent state is put in other files.
The item descriptions below use the following types:
``boolean``
one of (True, yes, on, 1, False, off, no, 0), case-insensitive
``strports string``
a Twisted listening-port specification string, like "``tcp:80``" or
"``tcp:3456:interface=127.0.0.1``". For a full description of the format,
see `the Twisted strports documentation
<https://twistedmatrix.com/documents/current/api/twisted.application.strports.html>`_.
Please note, if interface= is not specified, Tahoe-LAFS will attempt to
bind the port specified on all interfaces.
``FURL string``
a Foolscap endpoint identifier, like
``pb://soklj4y7eok5c3xkmjeqpw@192.168.69.247:44801/eqpwqtzm``
Node Types
==========
A node can be a client/server, an introducer, a statistics gatherer, or a
key generator.
Client/server nodes provide one or more of the following services:
* web-API service
* SFTP service
* FTP service
* drop-upload service
* helper service
* storage service.
A client/server that provides storage service (i.e. storing shares for
clients) is called a "storage server". If it provides any of the other
services, it is a "storage client" (a node can be both a storage server and a
storage client). A client/server node that provides web-API service is called
a "gateway".
Overall Node Configuration
==========================
This section controls the network behavior of the node overall: which ports
and IP addresses are used, when connections are timed out, etc. This
configuration applies to all node types and is independent of the services
that the node is offering.
If your node is behind a firewall or NAT device and you want other clients to
connect to it, you'll need to open a port in the firewall or NAT, and specify
that port number in the tub.port option. If behind a NAT, you *may* need to
set the ``tub.location`` option described below.
``[node]``
``nickname = (UTF-8 string, optional)``
This value will be displayed in management tools as this node's
"nickname". If not provided, the nickname will be set to "<unspecified>".
This string shall be a UTF-8 encoded Unicode string.
``web.port = (strports string, optional)``
This controls where the node's web server should listen, providing node
status and, if the node is a client/server, providing web-API service as
defined in `webapi.rst <frontends/webapi.rst>_`.
This file contains a Twisted "strports" specification such as "``3456``"
or "``tcp:3456:interface=127.0.0.1``". The "``tahoe create-node``" or
"``tahoe create-client``" commands set the ``web.port`` to
"``tcp:3456:interface=127.0.0.1``" by default; this is overridable by the
``--webport`` option. You can make it use SSL by writing
"``ssl:3456:privateKey=mykey.pem:certKey=cert.pem``" instead.
If this is not provided, the node will not run a web server.
``web.static = (string, optional)``
This controls where the ``/static`` portion of the URL space is
served. The value is a directory name (``~username`` is allowed, and
non-absolute names are interpreted relative to the node's basedir), which
can contain HTML and other files. This can be used to serve a
Javascript-based frontend to the Tahoe-LAFS node, or other services.
The default value is "``public_html``", which will serve
``BASEDIR/public_html`` . With the default settings,
``http://127.0.0.1:3456/static/foo.html`` will serve the contents of
``BASEDIR/public_html/foo.html`` .
``tub.port = (integer, optional)``
This controls which port the node uses to accept Foolscap connections
from other nodes. If not provided, the node will ask the kernel for any
available port. The port will be written to a separate file (named
``client.port`` or ``introducer.port``), so that subsequent runs will
re-use the same port.
``tub.location = (string, optional)``
In addition to running as a client, each Tahoe-LAFS node also runs as a
server, listening for connections from other Tahoe-LAFS clients. The node
announces its location by publishing a "FURL" (a string with some
connection hints) to the Introducer. The string it publishes can be found
in ``BASEDIR/private/storage.furl`` . The ``tub.location`` configuration
controls what location is published in this announcement.
If you don't provide ``tub.location``, the node will try to figure out a
useful one by itself, by using tools like "``ifconfig``" to determine the
set of IP addresses on which it can be reached from nodes both near and
far. It will also include the TCP port number on which it is listening
(either the one specified by ``tub.port``, or whichever port was assigned
by the kernel when ``tub.port`` is left unspecified).
You might want to override this value if your node lives behind a
firewall that is doing inbound port forwarding, or if you are using other
proxies such that the local IP address or port number is not the same one
that remote clients should use to connect. You might also want to control
this when using a Tor proxy to avoid revealing your actual IP address
through the Introducer announcement.
The value is a comma-separated string of host:port location hints, like
this::
123.45.67.89:8098,tahoe.example.com:8098,127.0.0.1:8098
A few examples:
* Emulate default behavior, assuming your host has IP address
123.45.67.89 and the kernel-allocated port number was 8098::
tub.port = 8098
tub.location = 123.45.67.89:8098,127.0.0.1:8098
* Use a DNS name so you can change the IP address more easily::
tub.port = 8098
tub.location = tahoe.example.com:8098
* Run a node behind a firewall (which has an external IP address) that
has been configured to forward port 7912 to our internal node's port
8098::
tub.port = 8098
tub.location = external-firewall.example.com:7912
* Run a node behind a Tor proxy (perhaps via ``torsocks``), in
client-only mode (i.e. we can make outbound connections, but other
nodes will not be able to connect to us). The literal
'``unreachable.example.org``' will not resolve, but will serve as a
reminder to human observers that this node cannot be reached. "Don't
call us.. we'll call you"::
tub.port = 8098
tub.location = unreachable.example.org:0
* Run a node behind a Tor proxy, and make the server available as a Tor
"hidden service". (This assumes that other clients are running their
node with ``torsocks``, such that they are prepared to connect to a
``.onion`` address.) The hidden service must first be configured in
Tor, by giving it a local port number and then obtaining a ``.onion``
name, using something in the ``torrc`` file like::
HiddenServiceDir /var/lib/tor/hidden_services/tahoe
HiddenServicePort 29212 127.0.0.1:8098
once Tor is restarted, the ``.onion`` hostname will be in
``/var/lib/tor/hidden_services/tahoe/hostname``. Then set up your
``tahoe.cfg`` like::
tub.port = 8098
tub.location = ualhejtq2p7ohfbb.onion:29212
Most users will not need to set ``tub.location``.
``log_gatherer.furl = (FURL, optional)``
If provided, this contains a single FURL string that is used to contact a
"log gatherer", which will be granted access to the logport. This can be
used to gather operational logs in a single place. Note that in previous
releases of Tahoe-LAFS, if an old-style ``BASEDIR/log_gatherer.furl``
file existed it would also be used in addition to this value, allowing
multiple log gatherers to be used at once. As of Tahoe-LAFS v1.9.0, an
old-style file is ignored and a warning will be emitted if one is
detected. This means that as of Tahoe-LAFS v1.9.0 you can have at most
one log gatherer per node. See ticket `#1423`_ about lifting this
restriction and letting you have multiple log gatherers.
.. _`#1423`: https://tahoe-lafs.org/trac/tahoe-lafs/ticket/1423
``timeout.keepalive = (integer in seconds, optional)``
``timeout.disconnect = (integer in seconds, optional)``
If ``timeout.keepalive`` is provided, it is treated as an integral number
of seconds, and sets the Foolscap "keepalive timer" to that value. For
each connection to another node, if nothing has been heard for a while,
we will attempt to provoke the other end into saying something. The
duration of silence that passes before sending the PING will be between
KT and 2*KT. This is mainly intended to keep NAT boxes from expiring idle
TCP sessions, but also gives TCP's long-duration keepalive/disconnect
timers some traffic to work with. The default value is 240 (i.e. 4
minutes).
If timeout.disconnect is provided, this is treated as an integral number
of seconds, and sets the Foolscap "disconnect timer" to that value. For
each connection to another node, if nothing has been heard for a while,
we will drop the connection. The duration of silence that passes before
dropping the connection will be between DT-2*KT and 2*DT+2*KT (please see
ticket `#521`_ for more details). If we are sending a large amount of
data to the other end (which takes more than DT-2*KT to deliver), we
might incorrectly drop the connection. The default behavior (when this
value is not provided) is to disable the disconnect timer.
See ticket `#521`_ for a discussion of how to pick these timeout values.
Using 30 minutes means we'll disconnect after 22 to 68 minutes of
inactivity. Receiving data will reset this timeout, however if we have
more than 22min of data in the outbound queue (such as 800kB in two
pipelined segments of 10 shares each) and the far end has no need to
contact us, our ping might be delayed, so we may disconnect them by
accident.
.. _`#521`: https://tahoe-lafs.org/trac/tahoe-lafs/ticket/521
``ssh.port = (strports string, optional)``
``ssh.authorized_keys_file = (filename, optional)``
This enables an SSH-based interactive Python shell, which can be used to
inspect the internal state of the node, for debugging. To cause the node
to accept SSH connections on port 8022 from the same keys as the rest of
your account, use::
[tub]
ssh.port = 8022
ssh.authorized_keys_file = ~/.ssh/authorized_keys
``tempdir = (string, optional)``
This specifies a temporary directory for the web-API server to use, for
holding large files while they are being uploaded. If a web-API client
attempts to upload a 10GB file, this tempdir will need to have at least
10GB available for the upload to complete.
The default value is the ``tmp`` directory in the node's base directory
(i.e. ``BASEDIR/tmp``), but it can be placed elsewhere. This directory is
used for files that usually (on a Unix system) go into ``/tmp``. The
string will be interpreted relative to the node's base directory.
Client Configuration
====================
``[client]``
``introducer.furl = (FURL string, mandatory)``
This FURL tells the client how to connect to the introducer. Each
Tahoe-LAFS grid is defined by an introducer. The introducer's FURL is
created by the introducer node and written into its private base
directory when it starts, whereupon it should be published to everyone
who wishes to attach a client to that grid
``helper.furl = (FURL string, optional)``
If provided, the node will attempt to connect to and use the given helper
for uploads. See `<helper.rst>`_ for details.
``key_generator.furl = (FURL string, optional)``
If provided, the node will attempt to connect to and use the given
key-generator service, using RSA keys from the external process rather
than generating its own.
``stats_gatherer.furl = (FURL string, optional)``
If provided, the node will connect to the given stats gatherer and
provide it with operational statistics.
``shares.needed = (int, optional) aka "k", default 3``
``shares.total = (int, optional) aka "N", N >= k, default 10``
``shares.happy = (int, optional) 1 <= happy <= N, default 7``
These three values set the default encoding parameters. Each time a new
file is uploaded, erasure-coding is used to break the ciphertext into
separate shares. There will be ``N`` (i.e. ``shares.total``) shares
created, and the file will be recoverable if any ``k``
(i.e. ``shares.needed``) shares are retrieved. The default values are
3-of-10 (i.e. ``shares.needed = 3``, ``shares.total = 10``). Setting
``k`` to 1 is equivalent to simple replication (uploading ``N`` copies of
the file).
These values control the tradeoff between storage overhead and
reliability. To a first approximation, a 1MB file will use (1MB *
``N``/``k``) of backend storage space (the actual value will be a bit
more, because of other forms of overhead). Up to ``N``-``k`` shares can
be lost before the file becomes unrecoverable. So large ``N``/``k``
ratios are more reliable, and small ``N``/``k`` ratios use less disk
space. ``N`` cannot be larger than 256, because of the 8-bit
erasure-coding algorithm that Tahoe-LAFS uses. ``k`` can not be greater
than ``N``. See `<performance.rst>`_ for more details.
``shares.happy`` allows you control over how well to "spread out" the
shares of an immutable file. For a successful upload, shares are
guaranteed to be initially placed on at least ``shares.happy`` distinct
servers, the correct functioning of any ``k`` of which is sufficient to
guarantee the availability of the uploaded file. This value should not be
larger than the number of servers on your grid.
A value of ``shares.happy`` <= ``k`` is allowed, but this is not
guaranteed to provide any redundancy if some servers fail or lose shares.
It may still provide redundancy in practice if ``N`` is greater than
the number of connected servers, because in that case there will typically
be more than one share on at least some storage nodes. However, since a
successful upload only guarantees that at least ``shares.happy`` shares
have been stored, the worst case is still that there is no redundancy.
(Mutable files use a different share placement algorithm that does not
currently consider this parameter.)
``mutable.format = sdmf or mdmf``
This value tells Tahoe-LAFS what the default mutable file format should
be. If ``mutable.format=sdmf``, then newly created mutable files will be
in the old SDMF format. This is desirable for clients that operate on
grids where some peers run older versions of Tahoe-LAFS, as these older
versions cannot read the new MDMF mutable file format. If
``mutable.format`` is ``mdmf``, then newly created mutable files will use
the new MDMF format, which supports efficient in-place modification and
streaming downloads. You can overwrite this value using a special
mutable-type parameter in the webapi. If you do not specify a value here,
Tahoe-LAFS will use SDMF for all newly-created mutable files.
Note that this parameter applies only to files, not to directories.
Mutable directories, which are stored in mutable files, are not
controlled by this parameter and will always use SDMF. We may revisit
this decision in future versions of Tahoe-LAFS.
See `<specifications/mutable.rst>`_ for details about mutable file
formats.
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:
HTTP
Tahoe runs a webserver by default on port 3456. This interface provides a
human-oriented "WUI", with pages to create, modify, and browse
directories and files, as well as a number of pages to check on the
status of your Tahoe node. It also provides a machine-oriented "WAPI",
with a REST-ful HTTP interface that can be used by other programs
(including the CLI tools). Please see `<frontends/webapi.rst>`_ for full
details, and the ``web.port`` and ``web.static`` config variables above.
The `<frontends/download-status.rst>`_ document also describes a few WUI
status pages.
CLI
The main "bin/tahoe" executable includes subcommands for manipulating the
filesystem, uploading/downloading files, and creating/running Tahoe
nodes. See `<frontends/CLI.rst>`_ for details.
SFTP, FTP
Tahoe can also run both SFTP and FTP servers, and map a username/password
pair to a top-level Tahoe directory. See `<frontends/FTP-and-SFTP.rst>`_
for instructions on configuring these services, and the ``[sftpd]`` and
``[ftpd]`` sections of ``tahoe.cfg``.
Drop-Upload
As of Tahoe-LAFS v1.9.0, a node running on Linux can be configured to
automatically upload files that are created or changed in a specified
local directory. See `<frontends/drop-upload.rst>`_ for details.
Storage Server Configuration
============================
``[storage]``
``enabled = (boolean, optional)``
If this is ``True``, the node will run a storage server, offering space
to other clients. If it is ``False``, the node will not run a storage
server, meaning that no shares will be stored on this node. Use ``False``
for clients who do not wish to provide storage service. The default value
is ``True``.
``readonly = (boolean, optional)``
If ``True``, the node will run a storage server but will not accept any
shares, making it effectively read-only. Use this for storage servers
that are being decommissioned: the ``storage/`` directory could be
mounted read-only, while shares are moved to other servers. Note that
this currently only affects immutable shares. Mutable shares (used for
directories) will be written and modified anyway. See ticket `#390
<https://tahoe-lafs.org/trac/tahoe-lafs/ticket/390>`_ for the current
status of this bug. The default value is ``False``.
``reserved_space = (str, optional)``
If provided, this value defines how much disk space is reserved: the
storage server will not accept any share that causes the amount of free
disk space to drop below this value. (The free space is measured by a
call to ``statvfs(2)`` on Unix, or ``GetDiskFreeSpaceEx`` on Windows, and
is the space available to the user account under which the storage server
runs.)
This string contains a number, with an optional case-insensitive scale
suffix, optionally followed by "B" or "iB". The supported scale suffixes
are "K", "M", "G", "T", "P" and "E", and a following "i" indicates to use
powers of 1024 rather than 1000. So "100MB", "100 M", "100000000B",
"100000000", and "100000kb" all mean the same thing. Likewise, "1MiB",
"1024KiB", "1024 Ki", and "1048576 B" all mean the same thing.
"``tahoe create-node``" generates a tahoe.cfg with
"``reserved_space=1G``", but you may wish to raise, lower, or remove the
reservation to suit your needs.
``expire.enabled =``
``expire.mode =``
``expire.override_lease_duration =``
``expire.cutoff_date =``
``expire.immutable =``
``expire.mutable =``
These settings control garbage collection, in which the server will
delete shares that no longer have an up-to-date lease on them. Please see
`<garbage-collection.rst>`_ for full details.
Running A Helper
================
A "helper" is a regular client node that also offers the "upload helper"
service.
``[helper]``
``enabled = (boolean, optional)``
If ``True``, the node will run a helper (see `<helper.rst>`_ for
details). The helper's contact FURL will be placed in
``private/helper.furl``, from which it can be copied to any clients that
wish to use it. Clearly nodes should not both run a helper and attempt to
use one: do not create ``helper.furl`` and also define
``[helper]enabled`` in the same node. The default is ``False``.
Running An Introducer
=====================
The introducer node uses a different ``.tac`` file (named
"``introducer.tac``"), and pays attention to the ``[node]`` section, but not
the others.
The Introducer node maintains some different state than regular client nodes.
``BASEDIR/private/introducer.furl``
This is generated the first time the introducer node is started, and used
again on subsequent runs, to give the introduction service a persistent
long-term identity. This file should be published and copied into new
client nodes before they are started for the first time.
Other Files in BASEDIR
======================
Some configuration is not kept in ``tahoe.cfg``, for the following reasons:
* it is generated by the node at startup, e.g. encryption keys. The node
never writes to ``tahoe.cfg``.
* it is generated by user action, e.g. the "``tahoe create-alias``" command.
In addition, non-configuration persistent state is kept in the node's base
directory, next to the configuration knobs.
This section describes these other files.
``private/node.pem``
This contains an SSL private-key certificate. The node generates this the
first time it is started, and re-uses it on subsequent runs. This
certificate allows the node to have a cryptographically-strong identifier
(the Foolscap "TubID"), and to establish secure connections to other nodes.
``storage/``
Nodes that host StorageServers will create this directory to hold shares of
files on behalf of other clients. There will be a directory underneath it
for each StorageIndex for which this node is holding shares. There is also
an "incoming" directory where partially-completed shares are held while
they are being received.
``tahoe-client.tac``
This file defines the client, by constructing the actual Client instance
each time the node is started. It is used by the "``twistd``" daemonization
program (in the ``-y`` mode), which is run internally by the "``tahoe
start``" command. This file is created by the "``tahoe create-node``" or
"``tahoe create-client``" commands.
``tahoe-introducer.tac``
This file is used to construct an introducer, and is created by the
"``tahoe create-introducer``" command.
``tahoe-key-generator.tac``
This file is used to construct a key generator, and is created by the
"``tahoe create-key-gernerator``" command.
``tahoe-stats-gatherer.tac``
This file is used to construct a statistics gatherer, and is created by the
"``tahoe create-stats-gatherer``" command.
``private/control.furl``
This file contains a FURL that provides access to a control port on the
client node, from which files can be uploaded and downloaded. This file is
created with permissions that prevent anyone else from reading it (on
operating systems that support such a concept), to insure that only the
owner of the client node can use this feature. This port is intended for
debugging and testing use.
``private/logport.furl``
This file contains a FURL that provides access to a 'log port' on the
client node, from which operational logs can be retrieved. Do not grant
logport access to strangers, because occasionally secret information may be
placed in the logs.
``private/helper.furl``
If the node is running a helper (for use by other clients), its contact
FURL will be placed here. See `<helper.rst>`_ for more details.
``private/root_dir.cap`` (optional)
The command-line tools will read a directory cap out of this file and use
it, if you don't specify a '--dir-cap' option or if you specify
'--dir-cap=root'.
``private/convergence`` (automatically generated)
An added secret for encrypting immutable files. Everyone who has this same
string in their ``private/convergence`` file encrypts their immutable files
in the same way when uploading them. This causes identical files to
"converge" -- to share the same storage space since they have identical
ciphertext -- which conserves space and optimizes upload time, but it also
exposes file contents to the possibility of a brute-force attack by people
who know that string. In this attack, if the attacker can guess most of the
contents of a file, then they can use brute-force to learn the remaining
contents.
So the set of people who know your ``private/convergence`` string is the
set of people who converge their storage space with you when you and they
upload identical immutable files, and it is also the set of people who
could mount such an attack.
The content of the ``private/convergence`` file is a base-32 encoded
string. If the file doesn't exist, then when the Tahoe-LAFS client starts
up it will generate a random 256-bit string and write the base-32 encoding
of this string into the file. If you want to converge your immutable files
with as many people as possible, put the empty string (so that
``private/convergence`` is a zero-length file).
Other files
===========
``logs/``
Each Tahoe-LAFS node creates a directory to hold the log messages produced
as the node runs. These logfiles are created and rotated by the
"``twistd``" daemonization program, so ``logs/twistd.log`` will contain the
most recent messages, ``logs/twistd.log.1`` will contain the previous ones,
``logs/twistd.log.2`` will be older still, and so on. ``twistd`` rotates
logfiles after they grow beyond 1MB in size. If the space consumed by
logfiles becomes troublesome, they should be pruned: a cron job to delete
all files that were created more than a month ago in this ``logs/``
directory should be sufficient.
``my_nodeid``
this is written by all nodes after startup, and contains a base32-encoded
(i.e. human-readable) NodeID that identifies this specific node. This
NodeID is the same string that gets displayed on the web page (in the
"which peers am I connected to" list), and the shortened form (the first
few characters) is recorded in various log messages.
``access.blacklist``
Gateway nodes may find it necessary to prohibit access to certain
files. The web-API has a facility to block access to filecaps by their
storage index, returning a 403 "Forbidden" error instead of the original
file. For more details, see the "Access Blacklist" section of
`<frontends/webapi.rst>`_.
Example
=======
The following is a sample ``tahoe.cfg`` file, containing values for some of
the keys described in the previous section. Note that this is not a
recommended configuration (most of these are not the default values), merely
a legal one.
::
[node]
nickname = Bob's Tahoe-LAFS Node
tub.port = 34912
tub.location = 123.45.67.89:8098,44.55.66.77:8098
web.port = 3456
log_gatherer.furl = pb://soklj4y7eok5c3xkmjeqpw@192.168.69.247:44801/eqpwqtzm
timeout.keepalive = 240
timeout.disconnect = 1800
ssh.port = 8022
ssh.authorized_keys_file = ~/.ssh/authorized_keys
[client]
introducer.furl = pb://ok45ssoklj4y7eok5c3xkmj@tahoe.example:44801/ii3uumo
helper.furl = pb://ggti5ssoklj4y7eok5c3xkmj@helper.tahoe.example:7054/kk8lhr
[storage]
enabled = True
readonly = True
reserved_space = 10000000000
[helper]
enabled = True
Old Configuration Files
=======================
Tahoe-LAFS releases before v1.3.0 had no ``tahoe.cfg`` file, and used
distinct files for each item. This is no longer supported and if you have
configuration in the old format you must manually convert it to the new
format for Tahoe-LAFS to detect it. See `<historical/configuration.rst>`_.