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	diff --git a/doc/sphinx/Pacemaker_Explained/resources.rst b/doc/sphinx/Pacemaker_Explained/resources.rst
	index 37d0b3bc5c..8c5f2f4243 100644
	--- a/doc/sphinx/Pacemaker_Explained/resources.rst
	+++ b/doc/sphinx/Pacemaker_Explained/resources.rst
	@@ -1,990 +1,995 @@
	.. _resource:

	Cluster Resources
	-----------------

	.. _s-resource-primitive:

	What is a Cluster Resource?
	###########################

	.. index::
	single: resource

	A resource is a service made highly available by a cluster.
	The simplest type of resource, a primitive resource, is described
	in this chapter. More complex forms, such as groups and clones,
	are described in later chapters.

	Every primitive resource has a resource agent. A resource agent is an
	external program that abstracts the service it provides and present a
	consistent view to the cluster.

	This allows the cluster to be agnostic about the resources it manages.
	The cluster doesn't need to understand how the resource works because
	it relies on the resource agent to do the right thing when given a
	start, stop or monitor command. For this reason, it is crucial
	that resource agents are well-tested.

	Typically, resource agents come in the form of shell scripts. However,
	they can be written using any technology (such as C, Python or Perl)
	that the author is comfortable with.

	.. _s-resource-supported:

	.. index::
	single: resource; class

	Resource Classes
	################

	Pacemaker supports several classes of agents:

	* OCF
	* LSB
	* Upstart
	* Systemd
	* Service
	* Fencing
	* Nagios Plugins

	.. index::
	single: resource; OCF
	single: OCF; resources
	single: Open Cluster Framework; resources

	Open Cluster Framework
	______________________

	The OCF standard [#]_ is basically an extension of the Linux Standard
	Base conventions for init scripts to:

	* support parameters,
	* make them self-describing, and
	* make them extensible

	OCF specs have strict definitions of the exit codes that actions must return [#]_.

	The cluster follows these specifications exactly, and giving the wrong
	exit code will cause the cluster to behave in ways you will likely
	find puzzling and annoying. In particular, the cluster needs to
	distinguish a completely stopped resource from one which is in some
	erroneous and indeterminate state.

	Parameters are passed to the resource agent as environment variables, with the
	special prefix ``OCF_RESKEY_``. So, a parameter which the user thinks
	of as ``ip`` will be passed to the resource agent as ``OCF_RESKEY_ip``. The
	number and purpose of the parameters is left to the resource agent; however,
	the resource agent should use the meta-data command to advertise any that it
	supports.

	The OCF class is the most preferred as it is an industry standard,
	highly flexible (allowing parameters to be passed to agents in a
	non-positional manner) and self-describing.

	For more information, see the
	`reference <http://www.linux-ha.org/wiki/OCF_Resource_Agents>`_ and
	the Resource Agents chapter of Pacemaker Administration.

	.. index::
	single: resource; LSB
	single: LSB; resources
	single: Linux Standard Base; resources

	Linux Standard Base
	___________________

	LSB resource agents are more commonly known as init scripts. If a full path
	is not given, they are assumed to be located in ``/etc/init.d``.

	Commonly, they are provided by the OS distribution. In order to be used
	with a Pacemaker cluster, they must conform to the LSB specification [#]_.

	.. warning::

	Many distributions or particular software packages claim LSB compliance
	but ship with broken init scripts. For details on how to check whether
	your init script is LSB-compatible, see the `Resource Agents` chapter of
	`Pacemaker Administration`. Common problematic violations of the LSB
	standard include:

	* Not implementing the ``status`` operation at all
	* Not observing the correct exit status codes for
	``start``/``stop``/``status`` actions
	* Starting a started resource returns an error
	* Stopping a stopped resource returns an error

	.. important::

	Remember to make sure the computer is `not` configured to start any
	services at boot time -- that should be controlled by the cluster.

	.. _s-resource-supported-systemd:

	.. index::
	single: Resource; Systemd
	single: Systemd; resources

	Systemd
	_______

	Some newer distributions have replaced the old
	`SysV <http://en.wikipedia.org/wiki/Init#SysV-style>`_ style of
	initialization daemons and scripts with an alternative called
	`Systemd <http://www.freedesktop.org/wiki/Software/systemd>`_.

	Pacemaker is able to manage these services `if they are present`.

	Instead of init scripts, systemd has `unit files`. Generally, the
	services (unit files) are provided by the OS distribution, but there
	are online guides for converting from init scripts [#]_.

	.. important::

	Remember to make sure the computer is `not` configured to start any
	services at boot time -- that should be controlled by the cluster.

	.. index::
	single: Resource; Upstart
	single: Upstart; resources

	Upstart
	_______

	Some newer distributions have replaced the old
	`SysV <http://en.wikipedia.org/wiki/Init#SysV-style>`_ style of
	initialization daemons (and scripts) with an alternative called
	`Upstart <http://upstart.ubuntu.com/>`_.

	Pacemaker is able to manage these services `if they are present`.

	Instead of init scripts, upstart has `jobs`. Generally, the
	services (jobs) are provided by the OS distribution.

	.. important::

	Remember to make sure the computer is `not` configured to start any
	services at boot time -- that should be controlled by the cluster.

	.. index::
	single: Resource; System Services
	single: System Service; resources

	System Services
	_______________

	Since there are various types of system services (``systemd``,
	``upstart``, and ``lsb``), Pacemaker supports a special ``service`` alias which
	intelligently figures out which one applies to a given cluster node.

	This is particularly useful when the cluster contains a mix of
	``systemd``, ``upstart``, and ``lsb``.

	In order, Pacemaker will try to find the named service as:

	* an LSB init script

	* a Systemd unit file

	* an Upstart job

	.. index::
	single: Resource; STONITH
	single: STONITH; resources

	STONITH
	_______

	The STONITH class is used exclusively for fencing-related resources. This is
	discussed later in :ref:`fencing`.

	.. index::
	single: Resource; Nagios Plugins
	single: Nagios Plugins; resources

	Nagios Plugins
	______________

	Nagios Plugins [#]_ allow us to monitor services on remote hosts.

	Pacemaker is able to do remote monitoring with the plugins `if they are
	present`.

	A common use case is to configure them as resources belonging to a resource
	container (usually a virtual machine), and the container will be restarted
	if any of them has failed. Another use is to configure them as ordinary
	resources to be used for monitoring hosts or services via the network.

	The supported parameters are same as the long options of the plugin.

	.. _primitive-resource:

	Resource Properties
	###################

	These values tell the cluster which resource agent to use for the resource,
	where to find that resource agent and what standards it conforms to.

	.. table:: Properties of a Primitive Resource

	+----------+------------------------------------------------------------------+
	\| Field \| Description \|
	+==========+==================================================================+
	\| id \| .. index:: \|
	\| \| single: id; resource \|
	\| \| single: resource; property, id \|
	\| \| \|
	\| \| Your name for the resource \|
	+----------+------------------------------------------------------------------+
	\| class \| .. index:: \|
	\| \| single: class; resource \|
	\| \| single: resource; property, class \|
	\| \| \|
	\| \| The standard the resource agent conforms to. Allowed values: \|
	\| \| ``lsb``, ``nagios``, ``ocf``, ``service``, ``stonith``, \|
	\| \| ``systemd``, ``upstart`` \|
	+----------+------------------------------------------------------------------+
	\| type \| .. index:: \|
	\| \| single: type; resource \|
	\| \| single: resource; property, type \|
	\| \| \|
	\| \| The name of the Resource Agent you wish to use. E.g. \|
	\| \| ``IPaddr`` or ``Filesystem`` \|
	+----------+------------------------------------------------------------------+
	\| provider \| .. index:: \|
	\| \| single: provider; resource \|
	\| \| single: resource; property, provider \|
	\| \| \|
	\| \| The OCF spec allows multiple vendors to supply the same resource \|
	\| \| agent. To use the OCF resource agents supplied by the Heartbeat \|
	\| \| project, you would specify ``heartbeat`` here. \|
	+----------+------------------------------------------------------------------+

	The XML definition of a resource can be queried with the crm_resource tool.
	For example:

	.. code-block:: none

	# crm_resource --resource Email --query-xml

	might produce:

	.. topic:: A system resource definition

	.. code-block:: xml

	<primitive id="Email" class="service" type="exim"/>

	.. note::

	One of the main drawbacks to system services (LSB, systemd or
	Upstart) resources is that they do not allow any parameters!

	.. topic:: An OCF resource definition

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<instance_attributes id="Public-IP-params">
	<nvpair id="Public-IP-ip" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	.. _resource_options:

	Resource Options
	################

	Resources have two types of options: meta-attributes and instance attributes.
	Meta-attributes apply to any type of resource, while instance attributes
	are specific to each resource agent.

	Resource Meta-Attributes
	________________________

	Meta-attributes are used by the cluster to decide how a resource should
	behave and can be easily set using the ``--meta`` option of the
	crm_resource command.

	.. table:: Meta-attributes of a Primitive Resource

	+----------------------------+----------------------------------+------------------------------------------------------+
	\| Field \| Default \| Description \|
	+============================+==================================+======================================================+
	\| priority \| 0 \| .. index:: \|
	\| \| \| single: priority; resource option \|
	\| \| \| single: resource; option, priority \|
	\| \| \| \|
	\| \| \| If not all resources can be active, the cluster \|
	\| \| \| will stop lower priority resources in order to \|
	\| \| \| keep higher priority ones active. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| target-role \| Started \| .. index:: \|
	\| \| \| single: target-role; resource option \|
	\| \| \| single: resource; option, target-role \|
	\| \| \| \|
	\| \| \| What state should the cluster attempt to keep this \|
	\| \| \| resource in? Allowed values: \|
	\| \| \| \|
	\| \| \| * ``Stopped:`` Force the resource to be stopped \|
	\| \| \| * ``Started:`` Allow the resource to be started \|
	\| \| \| (and in the case of :ref:`promotable clone \|
	\| \| \| resources <s-resource-promotable>`, promoted to \|
	\| \| \| master if appropriate) \|
	\| \| \| * ``Slave:`` Allow the resource to be started, but \|
	\| \| \| only in Slave mode if the resource is \|
	\| \| \| :ref:`promotable <s-resource-promotable>` \|
	\| \| \| * ``Master:`` Equivalent to ``Started`` \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| is-managed \| TRUE \| .. index:: \|
	\| \| \| single: is-managed; resource option \|
	\| \| \| single: resource; option, is-managed \|
	\| \| \| \|
	\| \| \| Is the cluster allowed to start and stop \|
	\| \| \| the resource? Allowed values: ``true``, ``false`` \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| maintenance \| FALSE \| .. index:: \|
	\| \| \| single: maintenance; resource option \|
	\| \| \| single: resource; option, maintenance \|
	\| \| \| \|
	\| \| \| Similar to the ``maintenance-mode`` \|
	\| \| \| :ref:`cluster option <cluster_options>`, but for \|
	\| \| \| a single resource. If true, the resource will not \|
	\| \| \| be started, stopped, or monitored on any node. This \|
	\| \| \| differs from ``is-managed`` in that monitors will \|
	\| \| \| not be run. Allowed values: ``true``, ``false`` \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	- \| resource-stickiness \| 1 for individual clone \| .. index:: \|
	- \| \| instances, 0 for all \| single: resource-stickiness; resource option \|
	- \| \| other resources \| single: resource; option, resource-stickiness \|
	+ \| resource-stickiness \| 1 for individual clone \| .. _resource-stickiness: \|
	+ \| \| instances, 0 for all \| \|
	+ \| \| other resources \| .. index:: \|
	+ \| \| \| single: resource-stickiness; resource option \|
	+ \| \| \| single: resource; option, resource-stickiness \|
	\| \| \| \|
	\| \| \| A score that will be added to the current node when \|
	\| \| \| a resource is already active. This allows running \|
	\| \| \| resources to stay where they are, even if they \|
	\| \| \| would be placed elsewhere if they were being \|
	\| \| \| started from a stopped state. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	- \| requires \| ``quorum`` for resources \| .. index:: \|
	- \| \| with a ``class`` of ``stonith``, \| single: requires; resource option \|
	- \| \| otherwise ``unfencing`` if \| single: resource; option, requires \|
	- \| \| unfencing is active in the \| \|
	- \| \| cluster, otherwise ``fencing`` \| Conditions under which the resource can be \|
	- \| \| if ``stonith-enabled`` is true, \| started. Allowed values: \|
	- \| \| otherwise ``quorum`` \| \|
	+ \| requires \| ``quorum`` for resources \| .. _requires: \|
	+ \| \| with a ``class`` of ``stonith``, \| \|
	+ \| \| otherwise ``unfencing`` if \| .. index:: \|
	+ \| \| unfencing is active in the \| single: requires; resource option \|
	+ \| \| cluster, otherwise ``fencing`` \| single: resource; option, requires \|
	+ \| \| if ``stonith-enabled`` is true, \| \|
	+ \| \| otherwise ``quorum`` \| Conditions under which the resource can be \|
	+ \| \| \| started. Allowed values: \|
	+ \| \| \| \|
	\| \| \| * ``nothing:`` can always be started \|
	\| \| \| * ``quorum:`` The cluster can only start this \|
	\| \| \| resource if a majority of the configured nodes \|
	\| \| \| are active \|
	\| \| \| * ``fencing:`` The cluster can only start this \|
	\| \| \| resource if a majority of the configured nodes \|
	\| \| \| are active and any failed or unknown nodes \|
	\| \| \| have been :ref:`fenced <fencing>` \|
	\| \| \| * ``unfencing:`` The cluster can only start this \|
	\| \| \| resource if a majority of the configured nodes \|
	\| \| \| are active and any failed or unknown nodes have \|
	\| \| \| been fenced and only on nodes that have been \|
	\| \| \| :ref:`unfenced <unfencing>` \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| migration-threshold \| INFINITY \| .. index:: \|
	\| \| \| single: migration-threshold; resource option \|
	\| \| \| single: resource; option, migration-threshold \|
	\| \| \| \|
	\| \| \| How many failures may occur for this resource on \|
	\| \| \| a node, before this node is marked ineligible to \|
	\| \| \| host this resource. A value of 0 indicates that this \|
	\| \| \| feature is disabled (the node will never be marked \|
	\| \| \| ineligible); by constrast, the cluster treats \|
	\| \| \| INFINITY (the default) as a very large but finite \|
	\| \| \| number. This option has an effect only if the \|
	\| \| \| failed operation specifies ``on-fail`` as \|
	\| \| \| ``restart`` (the default), and additionally for \|
	\| \| \| failed ``start`` operations, if the cluster \|
	\| \| \| property ``start-failure-is-fatal`` is ``false``. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| failure-timeout \| 0 \| .. index:: \|
	\| \| \| single: failure-timeout; resource option \|
	\| \| \| single: resource; option, failure-timeout \|
	\| \| \| \|
	\| \| \| How many seconds to wait before acting as if the \|
	\| \| \| failure had not occurred, and potentially allowing \|
	\| \| \| the resource back to the node on which it failed. \|
	\| \| \| A value of 0 indicates that this feature is \|
	\| \| \| disabled. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| multiple-active \| stop_start \| .. index:: \|
	\| \| \| single: multiple-active; resource option \|
	\| \| \| single: resource; option, multiple-active \|
	\| \| \| \|
	\| \| \| What should the cluster do if it ever finds the \|
	\| \| \| resource active on more than one node? Allowed \|
	\| \| \| values: \|
	\| \| \| \|
	\| \| \| * ``block``: mark the resource as unmanaged \|
	\| \| \| * ``stop_only``: stop all active instances and \|
	\| \| \| leave them that way \|
	\| \| \| * ``stop_start``: stop all active instances and \|
	\| \| \| start the resource in one location only \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| allow-migrate \| TRUE for ocf:pacemaker:remote \| Whether the cluster should try to "live migrate" \|
	\| \| resources, FALSE otherwise \| this resource when it needs to be moved (see \|
	\| \| \| :ref:`live-migration`) \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| container-attribute-target \| \| Specific to bundle resources; see \|
	\| \| \| :ref:`s-bundle-attributes` \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| remote-node \| \| The name of the Pacemaker Remote guest node this \|
	\| \| \| resource is associated with, if any. If \|
	\| \| \| specified, this both enables the resource as a \|
	\| \| \| guest node and defines the unique name used to \|
	\| \| \| identify the guest node. The guest must be \|
	\| \| \| configured to run the Pacemaker Remote daemon \|
	\| \| \| when it is started. WARNING: This value \|
	\| \| \| cannot overlap with any resource or node IDs. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| remote-port \| 3121 \| If ``remote-node`` is specified, the port on the \|
	\| \| \| guest used for its Pacemaker Remote connection. \|
	\| \| \| The Pacemaker Remote daemon on the guest must \|
	\| \| \| be configured to listen on this port. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| remote-addr \| value of ``remote-node`` \| If ``remote-node`` is specified, the IP \|
	\| \| \| address or hostname used to connect to the \|
	\| \| \| guest via Pacemaker Remote. The Pacemaker Remote \|
	\| \| \| daemon on the guest must be configured to accept \|
	\| \| \| connections on this address. \|
	+----------------------------+----------------------------------+------------------------------------------------------+
	\| remote-connect-timeout \| 60s \| If ``remote-node`` is specified, how long before \|
	\| \| \| a pending guest connection will time out. \|
	+----------------------------+----------------------------------+------------------------------------------------------+

	As an example of setting resource options, if you performed the following
	commands on an LSB Email resource:

	.. code-block:: none

	# crm_resource --meta --resource Email --set-parameter priority --parameter-value 100
	# crm_resource -m -r Email -p multiple-active -v block

	the resulting resource definition might be:

	.. topic:: An LSB resource with cluster options

	.. code-block:: xml

	<primitive id="Email" class="lsb" type="exim">
	<meta_attributes id="Email-meta_attributes">
	<nvpair id="Email-meta_attributes-priority" name="priority" value="100"/>
	<nvpair id="Email-meta_attributes-multiple-active" name="multiple-active" value="block"/>
	</meta_attributes>
	</primitive>

	In addition to the cluster-defined meta-attributes described above, you may
	also configure arbitrary meta-attributes of your own choosing. Most commonly,
	this would be done for use in :ref:`rules <rules>`. For example, an IT department
	might define a custom meta-attribute to indicate which company department each
	resource is intended for. To reduce the chance of name collisions with
	cluster-defined meta-attributes added in the future, it is recommended to use
	a unique, organization-specific prefix for such attributes.

	.. _s-resource-defaults:

	Setting Global Defaults for Resource Meta-Attributes
	____________________________________________________

	To set a default value for a resource option, add it to the
	``rsc_defaults`` section with ``crm_attribute``. For example,

	.. code-block:: none

	# crm_attribute --type rsc_defaults --name is-managed --update false

	would prevent the cluster from starting or stopping any of the
	resources in the configuration (unless of course the individual
	resources were specifically enabled by having their ``is-managed`` set to
	``true``).

	Resource Instance Attributes
	____________________________

	The resource agents of some resource classes (lsb, systemd and upstart not among them)
	can be given parameters which determine how they behave and which instance
	of a service they control.

	If your resource agent supports parameters, you can add them with the
	``crm_resource`` command. For example,

	.. code-block:: none

	# crm_resource --resource Public-IP --set-parameter ip --parameter-value 192.0.2.2

	would create an entry in the resource like this:

	.. topic:: An example OCF resource with instance attributes

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-addr" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	For an OCF resource, the result would be an environment variable
	called ``OCF_RESKEY_ip`` with a value of ``192.0.2.2``.

	The list of instance attributes supported by an OCF resource agent can be
	found by calling the resource agent with the ``meta-data`` command.
	The output contains an XML description of all the supported
	attributes, their purpose and default values.

	.. topic:: Displaying the metadata for the Dummy resource agent template

	.. code-block:: none

	# export OCF_ROOT=/usr/lib/ocf
	# $OCF_ROOT/resource.d/pacemaker/Dummy meta-data

	.. code-block:: xml

	<?xml version="1.0"?>
	<!DOCTYPE resource-agent SYSTEM "ra-api-1.dtd">
	<resource-agent name="Dummy" version="1.0">
	<version>1.0</version>

	<longdesc lang="en">
	This is a Dummy Resource Agent. It does absolutely nothing except
	keep track of whether its running or not.
	Its purpose in life is for testing and to serve as a template for RA writers.

	NB: Please pay attention to the timeouts specified in the actions
	section below. They should be meaningful for the kind of resource
	the agent manages. They should be the minimum advised timeouts,
	but they shouldn't/cannot cover _all_ possible resource
	instances. So, try to be neither overly generous nor too stingy,
	but moderate. The minimum timeouts should never be below 10 seconds.
	</longdesc>
	<shortdesc lang="en">Example stateless resource agent</shortdesc>

	<parameters>
	<parameter name="state" unique="1">
	<longdesc lang="en">
	Location to store the resource state in.
	</longdesc>
	<shortdesc lang="en">State file</shortdesc>
	<content type="string" default="/var/run/Dummy-default.state" />
	</parameter>

	<parameter name="fake" unique="0">
	<longdesc lang="en">
	Fake attribute that can be changed to cause a reload
	</longdesc>
	<shortdesc lang="en">Fake attribute that can be changed to cause a reload</shortdesc>
	<content type="string" default="dummy" />
	</parameter>

	<parameter name="op_sleep" unique="1">
	<longdesc lang="en">
	Number of seconds to sleep during operations. This can be used to test how
	the cluster reacts to operation timeouts.
	</longdesc>
	<shortdesc lang="en">Operation sleep duration in seconds.</shortdesc>
	<content type="string" default="0" />
	</parameter>

	</parameters>

	<actions>
	<action name="start" timeout="20" />
	<action name="stop" timeout="20" />
	<action name="monitor" timeout="20" interval="10" depth="0"/>
	<action name="reload" timeout="20" />
	<action name="migrate_to" timeout="20" />
	<action name="migrate_from" timeout="20" />
	<action name="validate-all" timeout="20" />
	<action name="meta-data" timeout="5" />
	</actions>
	</resource-agent>

	-.. _operation:
	-
	.. index::
	single: resource; action
	+ single: resource; operation
	+
	+.. _operation:

	Resource Operations
	###################

	Operations are actions the cluster can perform on a resource by calling the
	resource agent. Resource agents must support certain common operations such as
	start, stop, and monitor, and may implement any others.

	Operations may be explicitly configured for two purposes: to override defaults
	for options (such as timeout) that the cluster will use whenever it initiates
	the operation, and to run an operation on a recurring basis (for example, to
	monitor the resource for failure).

	.. topic:: An OCF resource with a non-default start timeout

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<operations>
	<op id="Public-IP-start" name="start" timeout="60s"/>
	</operations>
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-addr" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	Pacemaker identifies operations by a combination of name and interval, so this
	combination must be unique for each resource. That is, you should not configure
	two operations for the same resource with the same name and interval.

	.. _operation_properties:

	Operation Properties
	____________________

	Operation properties may be specified directly in the ``op`` element as
	XML attributes, or in a separate ``meta_attributes`` block as ``nvpair`` elements.
	XML attributes take precedence over ``nvpair`` elements if both are specified.

	.. table:: Properties of an Operation

	+----------------+-----------------------------------+-----------------------------------------------------+
	\| Field \| Default \| Description \|
	+================+===================================+=====================================================+
	\| id \| \| .. index:: \|
	\| \| \| single: id; action property \|
	\| \| \| single: action; property, id \|
	\| \| \| \|
	\| \| \| A unique name for the operation. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| name \| \| .. index:: \|
	\| \| \| single: name; action property \|
	\| \| \| single: action; property, name \|
	\| \| \| \|
	\| \| \| The action to perform. This can be any action \|
	\| \| \| supported by the agent; common values include \|
	\| \| \| ``monitor``, ``start``, and ``stop``. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| interval \| 0 \| .. index:: \|
	\| \| \| single: interval; action property \|
	\| \| \| single: action; property, interval \|
	\| \| \| \|
	\| \| \| How frequently (in seconds) to perform the \|
	\| \| \| operation. A value of 0 means "when needed". \|
	\| \| \| A positive value defines a recurring action, \|
	\| \| \| which is typically used with \|
	\| \| \| :ref:`monitor <s-resource-monitoring>`. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| timeout \| \| .. index:: \|
	\| \| \| single: timeout; action property \|
	\| \| \| single: action; property, timeout \|
	\| \| \| \|
	\| \| \| How long to wait before declaring the action \|
	\| \| \| has failed \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| on-fail \| Varies by action: \| .. index:: \|
	\| \| \| single: on-fail; action property \|
	\| \| * ``stop``: ``fence`` if \| single: action; property, on-fail \|
	\| \| ``stonith-enabled`` is true \| \|
	\| \| or ``block`` otherwise \| The action to take if this action ever fails. \|
	\| \| * ``demote``: ``on-fail`` of the \| Allowed values: \|
	\| \| ``monitor`` action with \| \|
	\| \| ``role`` set to ``Master``, if \| * ``ignore:`` Pretend the resource did not fail. \|
	\| \| present, enabled, and \| * ``block:`` Don't perform any further operations \|
	\| \| configured to a value other \| on the resource. \|
	\| \| than ``demote``, or ``restart`` \| * ``stop:`` Stop the resource and do not start \|
	\| \| otherwise \| it elsewhere. \|
	\| \| * all other actions: ``restart`` \| * ``demote:`` Demote the resource, without a \|
	\| \| \| full restart. This is valid only for ``promote`` \|
	\| \| \| actions, and for ``monitor`` actions with both \|
	\| \| \| a nonzero ``interval`` and ``role`` set to \|
	\| \| \| ``Master``; for any other action, a \|
	\| \| \| configuration error will be logged, and the \|
	\| \| \| default behavior will be used. (since 2.0.5) \|
	\| \| \| * ``restart:`` Stop the resource and start it \|
	\| \| \| again (possibly on a different node). \|
	\| \| \| * ``fence:`` STONITH the node on which the \|
	\| \| \| resource failed. \|
	\| \| \| * ``standby:`` Move all resources away from the \|
	\| \| \| node on which the resource failed. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| enabled \| TRUE \| .. index:: \|
	\| \| \| single: enabled; action property \|
	\| \| \| single: action; property, enabled \|
	\| \| \| \|
	\| \| \| If ``false``, ignore this operation definition. \|
	\| \| \| This is typically used to pause a particular \|
	\| \| \| recurring ``monitor`` operation; for instance, it \|
	\| \| \| can complement the respective resource being \|
	\| \| \| unmanaged (``is-managed=false``), as this alone \|
	\| \| \| will :ref:`not block any configured monitoring \|
	\| \| \| <s-monitoring-unmanaged>`. Disabling the operation \|
	\| \| \| does not suppress all actions of the given type. \|
	\| \| \| Allowed values: ``true``, ``false``. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| record-pending \| TRUE \| .. index:: \|
	\| \| \| single: record-pending; action property \|
	\| \| \| single: action; property, record-pending \|
	\| \| \| \|
	\| \| \| If ``true``, the intention to perform the operation \|
	\| \| \| is recorded so that GUIs and CLI tools can indicate \|
	\| \| \| that an operation is in progress. This is best set \|
	\| \| \| as an operation default \|
	\| \| \| (see :ref:`s-operation-defaults`). Allowed values: \|
	\| \| \| ``true``, ``false``. \|
	+----------------+-----------------------------------+-----------------------------------------------------+
	\| role \| \| .. index:: \|
	\| \| \| single: role; action property \|
	\| \| \| single: action; property, role \|
	\| \| \| \|
	\| \| \| Run the operation only on node(s) that the cluster \|
	\| \| \| thinks should be in the specified role. This only \|
	\| \| \| makes sense for recurring ``monitor`` operations. \|
	\| \| \| Allowed (case-sensitive) values: ``Stopped``, \|
	\| \| \| ``Started``, and in the case of :ref:`promotable \|
	\| \| \| clone resources <s-resource-promotable>`, \|
	\| \| \| ``Slave`` and ``Master``. \|
	+----------------+-----------------------------------+-----------------------------------------------------+

	.. note::

	When ``on-fail`` is set to ``demote``, recovery from failure by a successful demote
	causes the cluster to recalculate whether and where a new instance should be
	promoted. The node with the failure is eligible, so if master scores have not
	changed, it will be promoted again.

	There is no direct equivalent of ``migration-threshold`` for the master role, but
	the same effect can be achieved with a location constraint using a
	:ref:`rule <rules>` with a node attribute expression for the resource's fail
	count.

	For example, to immediately ban the master role from a node with any failed
	promote or master monitor:

	.. code-block:: xml

	<rsc_location id="loc1" rsc="my_primitive">
	<rule id="rule1" score="-INFINITY" role="Master" boolean-op="or">
	<expression id="expr1" attribute="fail-count-my_primitive#promote_0"
	operation="gte" value="1"/>
	<expression id="expr2" attribute="fail-count-my_primitive#monitor_10000"
	operation="gte" value="1"/>
	</rule>
	</rsc_location>

	This example assumes that there is a promotable clone of the ``my_primitive``
	resource (note that the primitive name, not the clone name, is used in the
	rule), and that there is a recurring 10-second-interval monitor configured for
	the master role (fail count attributes specify the interval in milliseconds).

	.. _s-resource-monitoring:

	Monitoring Resources for Failure
	________________________________

	When Pacemaker first starts a resource, it runs one-time ``monitor`` operations
	(referred to as probes) to ensure the resource is running where it's
	supposed to be, and not running where it's not supposed to be. (This behavior
	can be affected by the ``resource-discovery`` location constraint property.)

	Other than those initial probes, Pacemaker will not (by default) check that
	the resource continues to stay healthy [#]_. You must configure ``monitor``
	operations explicitly to perform these checks.

	.. topic:: An OCF resource with a recurring health check

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<operations>
	<op id="Public-IP-start" name="start" timeout="60s"/>
	<op id="Public-IP-monitor" name="monitor" interval="60s"/>
	</operations>
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-addr" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	By default, a ``monitor`` operation will ensure that the resource is running
	where it is supposed to. The ``target-role`` property can be used for further
	checking.

	For example, if a resource has one ``monitor`` operation with
	``interval=10 role=Started`` and a second ``monitor`` operation with
	``interval=11 role=Stopped``, the cluster will run the first monitor on any nodes
	it thinks should be running the resource, and the second monitor on any nodes
	that it thinks should not be running the resource (for the truly paranoid,
	who want to know when an administrator manually starts a service by mistake).

	.. note::

	Currently, monitors with ``role=Stopped`` are not implemented for
	:ref:`clone <s-resource-clone>` resources.

	.. _s-monitoring-unmanaged:

	Monitoring Resources When Administration is Disabled
	____________________________________________________

	Recurring ``monitor`` operations behave differently under various administrative
	settings:

	* When a resource is unmanaged (by setting ``is-managed=false``): No monitors
	will be stopped.

	If the unmanaged resource is stopped on a node where the cluster thinks it
	should be running, the cluster will detect and report that it is not, but it
	will not consider the monitor failed, and will not try to start the resource
	until it is managed again.

	Starting the unmanaged resource on a different node is strongly discouraged
	and will at least cause the cluster to consider the resource failed, and
	may require the resource's ``target-role`` to be set to ``Stopped`` then
	``Started`` to be recovered.

	* When a node is put into standby: All resources will be moved away from the
	node, and all ``monitor`` operations will be stopped on the node, except those
	specifying ``role`` as ``Stopped`` (which will be newly initiated if
	appropriate).

	* When the cluster is put into maintenance mode: All resources will be marked
	as unmanaged. All monitor operations will be stopped, except those
	specifying ``role`` as ``Stopped`` (which will be newly initiated if
	appropriate). As with single unmanaged resources, starting
	a resource on a node other than where the cluster expects it to be will
	cause problems.

	.. _s-operation-defaults:

	Setting Global Defaults for Operations
	______________________________________

	You can change the global default values for operation properties
	in a given cluster. These are defined in an ``op_defaults`` section
	of the CIB's ``configuration`` section, and can be set with
	``crm_attribute``. For example,

	.. code-block:: none

	# crm_attribute --type op_defaults --name timeout --update 20s

	would default each operation's ``timeout`` to 20 seconds. If an
	operation's definition also includes a value for ``timeout``, then that
	value would be used for that operation instead.

	When Implicit Operations Take a Long Time
	_________________________________________

	The cluster will always perform a number of implicit operations: ``start``,
	``stop`` and a non-recurring ``monitor`` operation used at startup to check
	whether the resource is already active. If one of these is taking too long,
	then you can create an entry for them and specify a longer timeout.

	.. topic:: An OCF resource with custom timeouts for its implicit actions

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<operations>
	<op id="public-ip-startup" name="monitor" interval="0" timeout="90s"/>
	<op id="public-ip-start" name="start" interval="0" timeout="180s"/>
	<op id="public-ip-stop" name="stop" interval="0" timeout="15min"/>
	</operations>
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-addr" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	Multiple Monitor Operations
	___________________________

	Provided no two operations (for a single resource) have the same name
	and interval, you can have as many ``monitor`` operations as you like.
	In this way, you can do a superficial health check every minute and
	progressively more intense ones at higher intervals.

	To tell the resource agent what kind of check to perform, you need to
	provide each monitor with a different value for a common parameter.
	The OCF standard creates a special parameter called ``OCF_CHECK_LEVEL``
	for this purpose and dictates that it is "made available to the
	resource agent without the normal ``OCF_RESKEY`` prefix".

	Whatever name you choose, you can specify it by adding an
	``instance_attributes`` block to the ``op`` tag. It is up to each
	resource agent to look for the parameter and decide how to use it.

	.. topic:: An OCF resource with two recurring health checks, performing
	different levels of checks specified via ``OCF_CHECK_LEVEL``.

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<operations>
	<op id="public-ip-health-60" name="monitor" interval="60">
	<instance_attributes id="params-public-ip-depth-60">
	<nvpair id="public-ip-depth-60" name="OCF_CHECK_LEVEL" value="10"/>
	</instance_attributes>
	</op>
	<op id="public-ip-health-300" name="monitor" interval="300">
	<instance_attributes id="params-public-ip-depth-300">
	<nvpair id="public-ip-depth-300" name="OCF_CHECK_LEVEL" value="20"/>
	</instance_attributes>
	</op>
	</operations>
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-level" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	Disabling a Monitor Operation
	_____________________________

	The easiest way to stop a recurring monitor is to just delete it.
	However, there can be times when you only want to disable it
	temporarily. In such cases, simply add ``enabled=false`` to the
	operation's definition.

	.. topic:: Example of an OCF resource with a disabled health check

	.. code-block:: xml

	<primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
	<operations>
	<op id="public-ip-check" name="monitor" interval="60s" enabled="false"/>
	</operations>
	<instance_attributes id="params-public-ip">
	<nvpair id="public-ip-addr" name="ip" value="192.0.2.2"/>
	</instance_attributes>
	</primitive>

	This can be achieved from the command line by executing:

	.. code-block:: none

	# cibadmin --modify --xml-text '<op id="public-ip-check" enabled="false"/>'

	Once you've done whatever you needed to do, you can then re-enable it with

	.. code-block:: none

	# cibadmin --modify --xml-text '<op id="public-ip-check" enabled="true"/>'

	.. [#] See https://github.com/ClusterLabs/OCF-spec/tree/master/ra. The
	Pacemaker implementation has been somewhat extended from the OCF specs.

	.. [#] The resource-agents source code includes the ocf-tester script,
	which can be useful in this regard.

	.. [#] See http://refspecs.linux-foundation.org/LSB_3.0.0/LSB-Core-generic/LSB-Core-generic/iniscrptact.html
	for the LSB Spec as it relates to init scripts.

	.. [#] For example, http://0pointer.de/blog/projects/systemd-for-admins-3.html

	.. [#] The project has two independent forks, hosted at
	https://www.nagios-plugins.org/ and https://www.monitoring-plugins.org/. Output
	from both projects' plugins is similar, so plugins from either project can be
	used with pacemaker.

	.. [#] Currently, anyway. Automatic monitoring operations may be added in a future
	version of Pacemaker.

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