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Signed-off-by: John Wilkins <john.wilkins@inktank.com>
832 lines
29 KiB
ReStructuredText
832 lines
29 KiB
ReStructuredText
==========================
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Monitor Config Reference
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==========================
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Understanding how to configure a :term:`Ceph Monitor` is an important part of
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building a reliable :term:`Ceph Storage Cluster`. **All Ceph Storage Clusters
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have at least one monitor**. A monitor configuration usually remains fairly
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consistent, but you can add, remove or replace a monitor in a cluster. See
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`Adding/Removing a Monitor`_ and `Add/Remove a Monitor (ceph-deploy)`_ for
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details.
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.. index:: Ceph Monitor; Paxos
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Background
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==========
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Ceph Monitors maintain a "master copy" of the :term:`cluster map`, which means a
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:term:`Ceph Client` can determine the location of all Ceph Monitors, Ceph OSD
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Daemons, and Ceph Metadata Servers just by connecting to one Ceph Monitor and
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retrieving a current cluster map. Before Ceph Clients can read from or write to
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Ceph OSD Daemons or Ceph Metadata Servers, they must connect to a Ceph Monitor
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first. With a current copy of the cluster map and the CRUSH algorithm, a Ceph
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Client can compute the location for any object. The ability to compute object
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locations allows a Ceph Client to talk directly to Ceph OSD Daemons, which is a
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very important aspect of Ceph's high scalability and performance. See
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`Scalability and High Availability`_ for additional details.
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The primary role of the Ceph Monitor is to maintain a master copy of the cluster
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map. Ceph Monitors also provide authentication and logging services. Ceph
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Monitors write all changes in the monitor services to a single Paxos instance,
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and Paxos writes the changes to a key/value store for strong consistency. Ceph
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Monitors can query the most recent version of the cluster map during sync
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operations. Ceph Monitors leverage the key/value store's snapshots and iterators
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(using leveldb) to perform store-wide synchronization.
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.. ditaa::
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/-------------\ /-------------\
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| Monitor | Write Changes | Paxos |
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| cCCC +-------------->+ cCCC |
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| | | |
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+-------------+ \------+------/
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| Auth | |
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+-------------+ | Write Changes
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| Log | |
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+-------------+ v
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| Monitor Map | /------+------\
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+-------------+ | Key / Value |
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| OSD Map | | Store |
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+-------------+ | cCCC |
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| PG Map | \------+------/
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+-------------+ ^
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| MDS Map | | Read Changes
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+-------------+ |
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| cCCC |*---------------------+
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\-------------/
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.. deprecated:: version 0.58
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In Ceph versions 0.58 and earlier, Ceph Monitors use a Paxos instance for
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each service and store the map as a file.
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.. index:: Ceph Monitor; cluster map
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Cluster Maps
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------------
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The cluster map is a composite of maps, including the monitor map, the OSD map,
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the placement group map and the metadata server map. The cluster map tracks a
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number of important things: which processes are ``in`` the Ceph Storage Cluster;
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which processes that are ``in`` the Ceph Storage Cluster are ``up`` and running
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or ``down``; whether, the placement groups are ``active`` or ``inactive``, and
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``clean`` or in some other state; and, other details that reflect the current
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state of the cluster such as the total amount of storage space, and the amount
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of storage used.
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When there is a significant change in the state of the cluster--e.g., a Ceph OSD
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Daemon goes down, a placement group falls into a degraded state, etc.--the
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cluster map gets updated to reflect the current state of the cluster.
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Additionally, the Ceph Monitor also maintains a history of the prior states of
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the cluster. The monitor map, OSD map, placement group map and metadata server
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map each maintain a history of their map versions. We call each version an
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"epoch."
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When operating your Ceph Storage Cluster, keeping track of these states is an
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important part of your system administration duties. See `Monitoring a Cluster`_
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and `Monitoring OSDs and PGs`_ for additional details.
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.. index:: high availability; quorum
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Monitor Quorum
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--------------
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Our Getting Started section provides a trivial `Ceph configuration file`_ that
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provides for one monitor in the test cluster. A cluster will run fine with a
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single monitor; however, **a single monitor is a single-point-of-failure**. To
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ensure high availability in a production Ceph Storage Cluster, you should run
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Ceph with multiple monitors so that the failure of a single monitor **WILL NOT**
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bring down your entire cluster.
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When a Ceph Storage Cluster runs multiple Ceph Monitors for high availability,
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Ceph Monitors use `Paxos`_ to establish consensus about the master cluster map.
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A consensus requires a majority of monitors running to establish a quorum for
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consensus about the cluster map (e.g., 1; 2 out of 3; 3 out of 5; 4 out of 6;
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etc.).
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.. index:: Ceph Monitor; consistency
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Consistency
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-----------
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When you add monitor settings to your Ceph configuration file, you need to be
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aware of some of the architectural aspects of Ceph Monitors. **Ceph imposes
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strict consistency requirements** for a Ceph monitor when discovering another
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Ceph Monitor within the cluster. Whereas, Ceph Clients and other Ceph daemons
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use the Ceph configuration file to discover monitors, monitors discover each
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other using the monitor map (monmap), not the Ceph configuration file.
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A Ceph Monitor always refers to the local copy of the monmap when discovering
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other Ceph Monitors in the Ceph Storage Cluster. Using the monmap instead of the
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Ceph configuration file avoids errors that could break the cluster (e.g., typos
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in ``ceph.conf`` when specifying a monitor address or port). Since monitors use
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monmaps for discovery and they share monmaps with clients and other Ceph
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daemons, **the monmap provides monitors with a strict guarantee that their
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consensus is valid.**
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Strict consistency also applies to updates to the monmap. As with any other
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updates on the Ceph Monitor, changes to the monmap always run through a
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distributed consensus algorithm called `Paxos`_. The Ceph Monitors must agree on
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each update to the monmap, such as adding or removing a Ceph Monitor, to ensure
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that each monitor in the quorum has the same version of the monmap. Updates to
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the monmap are incremental so that Ceph Monitors have the latest agreed upon
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version, and a set of previous versions. Maintaining a history enables a Ceph
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Monitor that has an older version of the monmap to catch up with the current
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state of the Ceph Storage Cluster.
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If Ceph Monitors discovered each other through the Ceph configuration file
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instead of through the monmap, it would introduce additional risks because the
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Ceph configuration files aren't updated and distributed automatically. Ceph
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Monitors might inadvertently use an older Ceph configuration file, fail to
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recognize a Ceph Monitor, fall out of a quorum, or develop a situation where
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`Paxos`_ isn't able to determine the current state of the system accurately.
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.. index:: Ceph Monitor; bootstrapping monitors
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Bootstrapping Monitors
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----------------------
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In most configuration and deployment cases, tools that deploy Ceph may help
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bootstrap the Ceph Monitors by generating a monitor map for you (e.g.,
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``mkcephfs``, ``ceph-deploy``, etc). A Ceph Monitor requires a few explicit
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settings:
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- **Filesystem ID**: The ``fsid`` is the unique identifier for your object
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store. Since you can run multiple clusters on the same hardware, you must
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specify the unique ID of the object store when bootstrapping a monitor.
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Deployment tools usually do this for you (e.g., ``mkcephfs`` or
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``ceph-deploy`` can call a tool like ``uuidgen``), but you may specify the
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``fsid`` manually too.
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- **Monitor ID**: A monitor ID is a unique ID assigned to each monitor within
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the cluster. It is an alphanumeric value, and by convention the identifier
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usually follows an alphabetical increment (e.g., ``a``, ``b``, etc.). This
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can be set in a Ceph configuration file (e.g., ``[mon.a]``, [mon.b]``, etc.),
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by a deployment tool, or using the ``ceph`` commandline.
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- **Keys**: The monitor must have secret keys. A deployment tool such as
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``mkcephfs`` or ``ceph-deploy`` usually does this for you, but you may
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perform this step manually too. See `Monitor Keyrings`_ for details.
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For additional details on bootstrapping, see `Bootstrapping a Monitor`_.
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.. index:: Ceph Monitor; configuring monitors
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Configuring Monitors
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====================
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To apply configuration settings to the entire cluster, enter the configuration
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settings under ``[global]``. To apply configuration settings to all monitors in
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your cluster, enter the configuration settings under ``[mon]``. To apply
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configuration settings to specific monitors, specify the monitor instance
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(e.g., ``[mon.a]``). By convention, monitor instance names use alpha notation.
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.. code-block:: ini
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[global]
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[mon]
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[mon.a]
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[mon.b]
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[mon.c]
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Minimum Configuration
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---------------------
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The bare minimum monitor settings for a Ceph monitor via the Ceph configuration
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file include a hostname and a monitor address for each monitor. You can configure
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these under ``[mon]`` or under the entry for a specific monitor.
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.. code-block:: ini
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[mon]
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mon host = hostname1,hostname2,hostname3
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mon addr = 10.0.0.10:6789,10.0.0.11:6789,10.0.0.12:6789
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.. code-block:: ini
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[mon.a]
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host = hostname1
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mon addr = 10.0.0.10:6789
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See the `Network Configuration Reference`_ for details.
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.. note:: This minimum configuration for monitors assumes that a deployment
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tool generates the ``fsid`` and the ``mon.`` key for you.
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Once you deploy a Ceph cluster, you **SHOULD NOT** change the IP address of
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the monitors. However, if you decide to change the monitor's IP address, you
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must follow a specific procedure. See `Changing a Monitor's IP Address`_ for
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details.
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Cluster ID
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----------
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Each Ceph Storage Cluster has a unique identifier (``fsid``). If specified, it
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usually appears under the ``[global]`` section of the configuration file.
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Deployment tools usually generate the ``fsid`` and store it in the monitor map,
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so the value may not appear in a configuration file. The ``fsid`` makes it
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possible to run daemons for multiple clusters on the same hardware.
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``fsid``
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:Description: The cluster ID. One per cluster.
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:Type: UUID
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:Required: Yes.
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:Default: N/A. May be generated by a deployment tool if not specified.
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.. note:: Do not set this value if you use a deployment tool that does
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it for you.
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.. index:: Ceph Monitor; initial members
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Initial Members
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---------------
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We recommend running a production Ceph Storage Cluster with at least three Ceph
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Monitors to ensure high availability. When you run multiple monitors, you may
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specify the initial monitors that must be members of the cluster in order to
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establish a quorum. This may reduce the time it takes for your cluster to come
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online.
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.. code-block:: ini
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[mon]
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mon initial members = a,b,c
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``mon initial members``
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:Description: The IDs of initial monitors in a cluster during startup. If
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specified, Ceph requires an odd number of monitors to form an
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initial quorum (e.g., 3).
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:Type: String
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:Default: None
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.. note:: A *majority* of monitors in your cluster must be able to reach
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each other in order to establish a quorum. You can decrease the initial
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number of monitors to establish a quorum with this setting.
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.. index:: Ceph Monitor; data path
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Data
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----
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Ceph provides a default path where Ceph Monitors store data. For optimal
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performance in a production Ceph Storage Cluster, we recommend running Ceph
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Monitors on separate hosts and drives from Ceph OSD Daemons. Ceph Monitors do
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lots of ``fsync()``, which can interfere with Ceph OSD Daemon workloads.
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In Ceph versions 0.58 and earlier, Ceph Monitors store their data in files. This
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approach allows users to inspect monitor data with common tools like ``ls``
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and ``cat``. However, it doesn't provide strong consistency.
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In Ceph versions 0.59 and later, Ceph Monitors store their data as key/value
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pairs. Ceph Monitors require `ACID`_ transactions. Using a data store prevents
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recovering Ceph Monitors from running corrupted versions through Paxos, and it
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enables multiple modification operations in one single atomic batch, among other
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advantages.
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Generally, we do not recommend changing the default data location. If you modify
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the default location, we recommend that you make it uniform across Ceph Monitors
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by setting it in the ``[mon]`` section of the configuration file.
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``mon data``
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:Description: The monitor's data location.
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:Type: String
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:Default: ``/var/lib/ceph/mon/$cluster-$id``
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.. index:: Ceph Storage Cluster; capacity planning, Ceph Monitor; capacity planning
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Storage Capacity
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----------------
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When a Ceph Storage Cluster gets close to its maximum capacity (i.e., ``mon osd
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full ratio``), Ceph prevents you from writing to or reading from Ceph OSD
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Daemons as a safety measure to prevent data loss. Therefore, letting a
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production Ceph Storage Cluster approach its full ratio is not a good practice,
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because it sacrifices high availability. The default full ratio is ``.95``, or
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95% of capacity. This a very aggressive setting for a test cluster with a small
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number of OSDs.
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.. tip:: When monitoring your cluster, be alert to warnings related to the
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``nearfull`` ratio. This means that a failure of some OSDs could result
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in a temporary service disruption if one or more OSDs fails. Consider adding
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more OSDs to increase storage capacity.
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A common scenario for test clusters involves a system administrator removing a
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Ceph OSD Daemon from the Ceph Storage Cluster to watch the cluster rebalance;
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then, removing another Ceph OSD Daemon, and so on until the Ceph Storage Cluster
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eventually reaches the full ratio and locks up. We recommend a bit of capacity
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planning even with a test cluster. Planning enables you to gauge how much spare
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capacity you will need in order to maintain high availability. Ideally, you want
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to plan for a series of Ceph OSD Daemon failures where the cluster can recover
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to an ``active + clean`` state without replacing those Ceph OSD Daemons
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immediately. You can run a cluster in an ``active + degraded`` state, but this
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is not ideal for normal operating conditions.
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The following diagram depicts a simplistic Ceph Storage Cluster containing 33
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Ceph Nodes with one Ceph OSD Daemon per host, each Ceph OSD Daemon reading from
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and writing to a 3TB drive. So this exemplary Ceph Storage Cluster has a maximum
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actual capacity of 99TB. With a ``mon osd full ratio`` of ``0.95``, if the Ceph
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Storage Cluster falls to 5TB of remaining capacity, the cluster will not allow
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Ceph Clients to read and write data. So the Ceph Storage Cluster's operating
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capacity is 95TB, not 99TB.
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.. ditaa::
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| Rack 1 | | Rack 2 | | Rack 3 | | Rack 4 | | Rack 5 | | Rack 6 |
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| cCCC | | cF00 | | cCCC | | cCCC | | cCCC | | cCCC |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 1 | | OSD 7 | | OSD 13 | | OSD 19 | | OSD 25 | | OSD 31 |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 2 | | OSD 8 | | OSD 14 | | OSD 20 | | OSD 26 | | OSD 32 |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 3 | | OSD 9 | | OSD 15 | | OSD 21 | | OSD 27 | | OSD 33 |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 4 | | OSD 10 | | OSD 16 | | OSD 22 | | OSD 28 | | Spare |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 5 | | OSD 11 | | OSD 17 | | OSD 23 | | OSD 29 | | Spare |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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| OSD 6 | | OSD 12 | | OSD 18 | | OSD 24 | | OSD 30 | | Spare |
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+--------+ +--------+ +--------+ +--------+ +--------+ +--------+
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It is normal in such a cluster for one or two OSDs to fail. A less frequent but
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reasonable scenario involves a rack's router or power supply failing, which
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brings down multiple OSDs simultaneously (e.g., OSDs 7-12). In such a scenario,
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you should still strive for a cluster that can remain operational and achieve an
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``active + clean`` state--even if that means adding a few hosts with additional
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OSDs in short order. If your capacity utilization is too high, you may not lose
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data, but you could still sacrifice data availability while resolving an outage
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within a failure domain if capacity utilization of the cluster exceeds the full
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ratio. For this reason, we recommend at least some rough capacity planning.
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Identify two numbers for your cluster:
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#. The number of OSDs.
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#. The total capacity of the cluster
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If you divide the total capacity of your cluster by the number of OSDs in your
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cluster, you will find the mean average capacity of an OSD within your cluster.
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Consider multiplying that number by the number of OSDs you expect will fail
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simultaneously during normal operations (a relatively small number). Finally
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multiply the capacity of the cluster by the full ratio to arrive at a maximum
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operating capacity; then, subtract the number of amount of data from the OSDs
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you expect to fail to arrive at a reasonable full ratio. Repeat the foregoing
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process with a higher number of OSD failures (e.g., a rack of OSDs) to arrive at
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a reasonable number for a near full ratio.
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.. code-block:: ini
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[global]
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mon osd full ratio = .80
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mon osd nearfull ratio = .70
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``mon osd full ratio``
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:Description: The percentage of disk space used before an OSD is
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considered ``full``.
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:Type: Float
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:Default: ``.95``
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``mon osd nearfull ratio``
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:Description: The percentage of disk space used before an OSD is
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considered ``nearfull``.
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:Type: Float
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:Default: ``.85``
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.. tip:: If some OSDs are nearfull, but others have plenty of capacity, you
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may have a problem with the CRUSH weight for the nearfull OSDs.
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.. index:: heartbeat
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Heartbeat
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---------
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Ceph monitors know about the cluster by requiring reports from each OSD, and by
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receiving reports from OSDs about the status of their neighboring OSDs. Ceph
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provides reasonable default settings for monitor/OSD interaction; however, you
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may modify them as needed. See `Monitor/OSD Interaction`_ for details.
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.. index:: Ceph Monitor; leader, Ceph Monitor; provider, Ceph Monitor; requester, Ceph Monitor; synchronization
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Monitor Store Synchronization
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-----------------------------
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When you run a production cluster with multiple monitors (recommended), each
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monitor checks to see if a neighboring monitor has a more recent version of the
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cluster map (e.g., a map in a neighboring monitor with one or more epoch numbers
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higher than the most current epoch in the map of the instant monitor).
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Periodically, one monitor in the cluster may fall behind the other monitors to
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the point where it must leave the quorum, synchronize to retrieve the most
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current information about the cluster, and then rejoin the quorum. For the
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purposes of synchronization, monitors may assume one of three roles:
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#. **Leader**: The `Leader` is the first monitor to achieve the most recent
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Paxos version of the cluster map.
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#. **Provider**: The `Provider` is a monitor that has the most recent version
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of the cluster map, but wasn't the first to achieve the most recent version.
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#. **Requester:** A `Requester` is a monitor that has fallen behind the leader
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and must synchronize in order to retrieve the most recent information about
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the cluster before it can rejoin the quorum.
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These roles enable a leader to delegate synchronization duties to a provider,
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which prevents synchronization requests from overloading the leader--improving
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performance. In the following diagram, the requester has learned that it has
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fallen behind the other monitors. The requester asks the leader to synchronize,
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and the leader tells the requester to synchronize with a provider.
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.. ditaa:: +-----------+ +---------+ +----------+
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| Requester | | Leader | | Provider |
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+-----------+ +---------+ +----------+
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| | |
|
|
| Ask to Synchronize | |
|
|
|------------------->| |
|
|
| | |
|
|
|<-------------------| |
|
|
| Tell Requester to | |
|
|
| Sync with Provider | |
|
|
| | |
|
|
| Synchronize |
|
|
|--------------------+-------------------->|
|
|
| | |
|
|
|<-------------------+---------------------|
|
|
| Send Chunk to Requester |
|
|
| (repeat as necessary) |
|
|
| Requester Acks Chuck to Provider |
|
|
|--------------------+-------------------->|
|
|
| |
|
|
| Sync Complete |
|
|
| Notification |
|
|
|------------------->|
|
|
| |
|
|
|<-------------------|
|
|
| Ack |
|
|
| |
|
|
|
|
|
|
Synchronization always occurs when a new monitor joins the cluster. During
|
|
runtime operations, monitors may receive updates to the cluster map at different
|
|
times. This means the leader and provider roles may migrate from one monitor to
|
|
another. If this happens while synchronizing (e.g., a provider falls behind the
|
|
leader), the provider can terminate synchronization with a requester.
|
|
|
|
Once synchronization is complete, Ceph requires trimming across the cluster.
|
|
Trimming requires that the placement groups are ``active + clean``.
|
|
|
|
|
|
``mon sync trim timeout``
|
|
|
|
:Description:
|
|
:Type: Double
|
|
:Default: ``30.0``
|
|
|
|
|
|
``mon sync heartbeat timeout``
|
|
|
|
:Description:
|
|
:Type: Double
|
|
:Default: ``30.0``
|
|
|
|
|
|
``mon sync heartbeat interval``
|
|
|
|
:Description:
|
|
:Type: Double
|
|
:Default: ``5.0``
|
|
|
|
|
|
``mon sync backoff timeout``
|
|
|
|
:Description:
|
|
:Type: Double
|
|
:Default: ``30.0``
|
|
|
|
|
|
``mon sync timeout``
|
|
|
|
:Description:
|
|
:Type: Double
|
|
:Default: ``30.0``
|
|
|
|
|
|
``mon sync max retries``
|
|
|
|
:Description:
|
|
:Type: Integer
|
|
:Default: ``5``
|
|
|
|
|
|
``mon sync max payload size``
|
|
|
|
:Description: The maximum size for a sync payload.
|
|
:Type: 32-bit Integer
|
|
:Default: ``1045676``
|
|
|
|
|
|
``mon accept timeout``
|
|
|
|
:Description: Number of seconds the Leader will wait for the Requester(s) to
|
|
accept a Paxos update. It is also used during the Paxos recovery
|
|
phase for similar purposes.
|
|
|
|
:Type: Float
|
|
:Default: ``10.0``
|
|
|
|
|
|
``paxos propose interval``
|
|
|
|
:Description: Gather updates for this time interval before proposing a map update.
|
|
:Type: Double
|
|
:Default: ``1.0``
|
|
|
|
|
|
``paxos min wait``
|
|
|
|
:Description: The minimum amount of time to gather updates after a period of
|
|
inactivity.
|
|
|
|
:Type: Double
|
|
:Default: ``0.05``
|
|
|
|
|
|
``paxos trim tolerance``
|
|
|
|
:Description: The number of extra proposals tolerated before trimming.
|
|
:Type: Integer
|
|
:Default: ``30``
|
|
|
|
|
|
``paxos trim disabled max versions``
|
|
|
|
:Description: The maximimum number of version allowed to pass without trimming.
|
|
:Type: Integer
|
|
:Default: ``100``
|
|
|
|
|
|
``mon lease``
|
|
|
|
:Description: The length (in seconds) of the lease on the monitor's versions.
|
|
:Type: Float
|
|
:Default: ``5``
|
|
|
|
|
|
``mon lease renew interval``
|
|
|
|
:Description: The interval (in seconds) for the Leader to renew the other
|
|
monitor's leases.
|
|
|
|
:Type: Float
|
|
:Default: ``3``
|
|
|
|
|
|
``mon lease ack timeout``
|
|
|
|
:Description: The number of seconds the Leader will wait for the Providers to
|
|
acknowledge the lease extension.
|
|
|
|
:Type: Float
|
|
:Default: ``10.0``
|
|
|
|
|
|
``mon min osdmap epochs``
|
|
|
|
:Description: Minimum number of OSD map epochs to keep at all times.
|
|
:Type: 32-bit Integer
|
|
:Default: ``500``
|
|
|
|
|
|
``mon max pgmap epochs``
|
|
|
|
:Description: Maximum number of PG map epochs the monitor should keep.
|
|
:Type: 32-bit Integer
|
|
:Default: ``500``
|
|
|
|
|
|
``mon max log epochs``
|
|
|
|
:Description: Maximum number of Log epochs the monitor should keep.
|
|
:Type: 32-bit Integer
|
|
:Default: ``500``
|
|
|
|
|
|
|
|
|
|
Slurp
|
|
-----
|
|
|
|
In Ceph version 0.58 and earlier, when a Paxos service drifts beyond a given
|
|
number of versions, Ceph triggers the `slurp` mechanism, which establishes a
|
|
connection with the quorum Leader and obtains every single version the Leader
|
|
has for every service that has drifted. In Ceph versions 0.59 and later, slurp
|
|
will not work, because there is a single Paxos instance for all services.
|
|
|
|
.. deprecated:: 0.58
|
|
|
|
``paxos max join drift``
|
|
|
|
:Description: The maximum Paxos iterations before we must first sync the
|
|
monitor data stores.
|
|
:Type: Integer
|
|
:Default: ``10``
|
|
|
|
|
|
``mon slurp timeout``
|
|
|
|
:Description: The number of seconds the monitor has to recover using slurp
|
|
before the process is aborted and the monitor bootstraps.
|
|
|
|
:Type: Double
|
|
:Default: ``10.0``
|
|
|
|
|
|
``mon slurp bytes``
|
|
|
|
:Description: Limits the slurp messages to the specified number of bytes.
|
|
:Type: 32-bit Integer
|
|
:Default: ``256 * 1024``
|
|
|
|
|
|
.. index:: Ceph Monitor; clock
|
|
|
|
Clock
|
|
-----
|
|
|
|
|
|
``clock offset``
|
|
|
|
:Description: How much to offset the system clock. See ``Clock.cc`` for details.
|
|
:Type: Double
|
|
:Default: ``0``
|
|
|
|
|
|
.. deprecated:: 0.58
|
|
|
|
``mon tick interval``
|
|
|
|
:Description: A monitor's tick interval in seconds.
|
|
:Type: 32-bit Integer
|
|
:Default: ``5``
|
|
|
|
|
|
``mon clock drift allowed``
|
|
|
|
:Description: The clock drift in seconds allowed between monitors.
|
|
:Type: Float
|
|
:Default: ``.050``
|
|
|
|
|
|
``mon clock drift warn backoff``
|
|
|
|
:Description: Exponential backoff for clock drift warnings
|
|
:Type: Float
|
|
:Default: ``5``
|
|
|
|
|
|
``mon timecheck interval``
|
|
|
|
:Description: The time check interval (clock drift check) in seconds
|
|
for the leader.
|
|
|
|
:Type: Float
|
|
:Default: ``300.0``
|
|
|
|
|
|
|
|
Client
|
|
------
|
|
|
|
``mon client hung interval``
|
|
|
|
:Description: The client will try a new monitor every ``N`` seconds until it
|
|
establishes a connection.
|
|
|
|
:Type: Double
|
|
:Default: ``3.0``
|
|
|
|
|
|
``mon client ping interval``
|
|
|
|
:Description: The client will ping the monitor every ``N`` seconds.
|
|
:Type: Double
|
|
:Default: ``10.0``
|
|
|
|
|
|
``mon client max log entries per message``
|
|
|
|
:Description: The maximum number of log entries a monitor will generate
|
|
per client message.
|
|
|
|
:Type: Integer
|
|
:Default: ``1000``
|
|
|
|
|
|
``mon client bytes``
|
|
|
|
:Description: The amount of client message data allowed in memory (in bytes).
|
|
:Type: 64-bit Integer Unsigned
|
|
:Default: ``100ul << 20``
|
|
|
|
|
|
|
|
Miscellaneous
|
|
=============
|
|
|
|
|
|
``mon max osd``
|
|
|
|
:Description: The maximum number of OSDs allowed in the cluster.
|
|
:Type: 32-bit Integer
|
|
:Default: ``10000``
|
|
|
|
``mon globalid prealloc``
|
|
|
|
:Description: The number of global IDs to pre-allocate for clients and daemons in the cluster.
|
|
:Type: 32-bit Integer
|
|
:Default: ``100``
|
|
|
|
``mon sync fs threshold``
|
|
|
|
:Description: Synchronize with the filesystem when writing the specified number of objects. Set it to ``0`` to disable it.
|
|
:Type: 32-bit Integer
|
|
:Default: ``5``
|
|
|
|
``mon subscribe interval``
|
|
|
|
:Description: The refresh interval (in seconds) for subscriptions. The
|
|
subscription mechanism enables obtaining the cluster maps
|
|
and log information.
|
|
|
|
:Type: Double
|
|
:Default: ``300``
|
|
|
|
|
|
``mon stat smooth intervals``
|
|
|
|
:Description: Ceph will smooth statistics over the last ``N`` PG maps.
|
|
:Type: Integer
|
|
:Default: ``2``
|
|
|
|
|
|
``mon probe timeout``
|
|
|
|
:Description: Number of seconds the monitor will wait to find peers before bootstrapping.
|
|
:Type: Double
|
|
:Default: ``2.0``
|
|
|
|
|
|
``mon daemon bytes``
|
|
|
|
:Description: The message memory cap for metadata server and OSD messages (in bytes).
|
|
:Type: 64-bit Integer Unsigned
|
|
:Default: ``400ul << 20``
|
|
|
|
|
|
``mon max log entries per event``
|
|
|
|
:Description: The maximum number of log entries per event.
|
|
:Type: Integer
|
|
:Default: ``4096``
|
|
|
|
|
|
|
|
.. _Paxos: http://en.wikipedia.org/wiki/Paxos_(computer_science)
|
|
.. _Monitor Keyrings: ../../operations/authentication#monitor-keyrings
|
|
.. _Ceph configuration file: ../../../start/quick-start/#add-a-configuration-file
|
|
.. _Network Configuration Reference: ../network-config-ref
|
|
.. _ACID: http://en.wikipedia.org/wiki/ACID
|
|
.. _Adding/Removing a Monitor: ../../operations/add-or-rm-mons
|
|
.. _Add/Remove a Monitor (ceph-deploy): ../../deployment/ceph-deploy-mon
|
|
.. _Monitoring a Cluster: ../../operations/monitoring
|
|
.. _Monitoring OSDs and PGs: ../../operations/monitoring-osd-pg
|
|
.. _Bootstrapping a Monitor: ../../../dev/mon-bootstrap
|
|
.. _Changing a Monitor's IP Address: ../../operations/add-or-rm-mons#changing-a-monitor-s-ip-address
|
|
.. _Monitor/OSD Interaction: ../mon-osd-interaction
|
|
.. _Scalability and High Availability: ../../../architecture#scalability-and-high-availability |