diff --git a/doc/Pacemaker_Explained/en-US/Ch-Resources.txt b/doc/Pacemaker_Explained/en-US/Ch-Resources.txt
index 5d5fa333ca..b0115fb605 100644
--- a/doc/Pacemaker_Explained/en-US/Ch-Resources.txt
+++ b/doc/Pacemaker_Explained/en-US/Ch-Resources.txt
@@ -1,760 +1,770 @@
 = Cluster Resources =
 
 == What is a Cluster Resource? ==
 
 indexterm:[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]]
 == Resource Classes ==
 
 indexterm:[Resource,class]
 
 Pacemaker supports several classes of agents:
 
 * OCF
 * LSB
 * Upstart
 * Systemd
 * Service
 * Fencing
 * Nagios Plugins
 
 === Open Cluster Framework ===
 
 indexterm:[Resource,OCF]
 indexterm:[OCF,Resources]
 indexterm:[Open Cluster Framework,Resources]
 
 The OCF standard
 footnote:[See
 http://www.opencf.org/cgi-bin/viewcvs.cgi/specs/ra/resource-agent-api.txt?rev=HEAD
  -- at least as it relates to resource agents.  The Pacemaker implementation has
 been somewhat extended from the OCF specs, but none of those changes are
 incompatible with the original OCF specification.]
 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.
 footnote:[
 The resource-agents source code includes the `ocf-tester` script, which
 can be useful in this regard.
 ]
 
 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
 http://www.linux-ha.org/wiki/OCF_Resource_Agents[reference] and
 <<ap-ocf>>.
 
 === Linux Standard Base ===
 indexterm:[Resource,LSB]
 indexterm:[LSB,Resources]
 indexterm:[Linux Standard Base,Resources]
 
 LSB resource agents are those found in +/etc/init.d+.
 
 Generally, they are provided by the OS distribution and, in order to be used
 with the cluster, they must conform to the LSB Spec.
 footnote:[
 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.
 ]
 
 [WARNING]
 ====
 Many distributions claim LSB compliance but ship with broken init
 scripts.  For details on how to check whether your init script is
 LSB-compatible, see <<ap-lsb>>. 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.
 ====
 
 === Systemd ===
 indexterm:[Resource,Systemd]
 indexterm:[Systemd,Resources]
 
 Some newer distributions have replaced the old
 http://en.wikipedia.org/wiki/Init#SysV-style["SysV"] style of
 initialization daemons and scripts with an alternative called
 http://www.freedesktop.org/wiki/Software/systemd[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.
 footnote:[For example,
 http://0pointer.de/blog/projects/systemd-for-admins-3.html]
 
 [IMPORTANT]
 ====
 Remember to make sure the computer is _not_ configured to start any
 services at boot time -- that should be controlled by the cluster.
 ====
 
 === Upstart ===
 indexterm:[Resource,Upstart]
 indexterm:[Upstart,Resources]
 
 Some newer distributions have replaced the old
 http://en.wikipedia.org/wiki/Init#SysV-style["SysV"] style of
 initialization daemons (and scripts) with an alternative called
 http://upstart.ubuntu.com/[Upstart].
 
 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.
 ====
 
 === System Services ===
 indexterm:[Resource,System Services]
 indexterm:[System Service,Resources]
 
 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
 
 === STONITH ===
 indexterm:[Resource,STONITH]
 indexterm:[STONITH,Resources]
 
 The STONITH class is used exclusively for fencing-related resources.  This is
 discussed later in <<ch-stonith>>.
 
 === Nagios Plugins ===
 indexterm:[Resource,Nagios Plugins]
 indexterm:[Nagios Plugins,Resources]
 
 Nagios Plugins
 footnote:[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.]
 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.
 
 .Properties of a Primitive Resource
 [width="95%",cols="1m,6<",options="header",align="center"]
 |=========================================================
 
 |Field
 |Description
 
 |id
 |Your name for the resource
  indexterm:[id,Resource]
  indexterm:[Resource,Property,id]
 
 |class
 
 |The standard the resource agent conforms to. Allowed values:
 +lsb+, +nagios+, +ocf+, +service+, +stonith+, +systemd+, +upstart+
  indexterm:[class,Resource]
  indexterm:[Resource,Property,class]
 
 |type
 |The name of the Resource Agent you wish to use. E.g. +IPaddr+ or +Filesystem+
  indexterm:[type,Resource]
  indexterm:[Resource,Property,type]
 
 |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.
  indexterm:[provider,Resource]
  indexterm:[Resource,Property,provider]
 
 |=========================================================
 
 The XML definition of a resource can be queried with the `crm_resource` tool.
 For example:
 
 ----
 # crm_resource --resource Email --query-xml
 ----
 
 might produce:
 
 .A system resource definition
 =====
 [source,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!
 =====
 
 ////
 See https://tools.ietf.org/html/rfc5737 for choice of example IP address
 ////
 
 .An OCF resource definition
 =====
 [source,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>
 -------
 =====
 
 [[s-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.
 
 .Meta-attributes of a Primitive Resource
 [width="95%",cols="2m,2,5<a",options="header",align="center"]
 |=========================================================
 
 |Field
 |Default
 |Description
 
 |priority
 |0
 |If not all resources can be active, the cluster will stop lower
 priority resources in order to keep higher priority ones active.
 indexterm:[priority,Resource Option]
 indexterm:[Resource,Option,priority]
 
 |target-role
 |started
 |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 (In the case of
   <<s-resource-multistate,multi-state>> resources, they will not promoted to
   master)
 * +master:+ Allow the resource to be started and, if appropriate, promoted
 indexterm:[target-role,Resource Option]
 indexterm:[Resource,Option,target-role]
 
 |is-managed
 |TRUE
 |Is the cluster allowed to start and stop the resource?  Allowed
  values: +true+, +false+
  indexterm:[is-managed,Resource Option]
  indexterm:[Resource,Option,is-managed]
 
 |resource-stickiness
 |value of +resource-stickiness+ in the +rsc_defaults+ section
 |How much does the resource prefer to stay where it is?
  indexterm:[resource-stickiness,Resource Option]
  indexterm:[Resource,Option,resource-stickiness]
 
 |requires
 |fencing (unless +stonith-enabled+ is +false+ or +class+ is
 +stonith+, in which case it defaults to quorum)
 |Conditions under which the resource can be started ('Since 1.1.8')
 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 powered off
 * +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 powered off _and_ only on nodes that have been 'unfenced'
 
 indexterm:[requires,Resource Option]
 indexterm:[Resource,Option,requires]
 
 |migration-threshold
 |INFINITY
 |How many failures may occur for this resource on a node, before this
  node is marked ineligible to host this resource. A value of INFINITY
  indicates that this feature is disabled.
  indexterm:[migration-threshold,Resource Option]
  indexterm:[Resource,Option,migration-threshold]
 
 |failure-timeout
 |0
 |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.
  indexterm:[failure-timeout,Resource Option]
  indexterm:[Resource,Option,failure-timeout]
 
 |multiple-active
 |stop_start
 |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
 
 indexterm:[multiple-active,Resource Option]
 indexterm:[Resource,Option,multiple-active]
 
 |remote-node
 |
 |The name of the remote-node this resource defines.  This both enables the
 resource as a remote-node and defines the unique name used to identify the
 remote-node. If no other parameters are set, this value will also be assumed as
 the hostname to connect to at the port specified by +remote-port+. +WARNING:+
 This value cannot overlap with any resource or node IDs. If not specified,
 this feature is disabled.
 
 |remote-port
 |3121
 |Port to use for the guest connection to pacemaker_remote
 
 |remote-addr
 |value of +remote-node+
 |The IP address or hostname to connect to if remote-node's name is not the
 hostname of the guest.
 
 |+remote-connect-timeout+
 |60s
 |How long before a pending guest connection will time out.
 
 |=========================================================
 
 [NOTE]
 ====
 Support for remote nodes was added in pacemaker 1.1.10. If you are using an
 earlier version, options related to remote nodes will not be available.
 ====
 
 As an example of setting resource options, if you performed the following
 commands on an LSB Email resource:
 
 -------
 # 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:
 
 .An LSB resource with cluster options
 =====
 [source,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>
 -------
 =====
 
 [[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,
 
 ----
 # 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,
 
 ----
 # crm_resource --resource Public-IP --set-parameter ip --parameter-value 192.0.2.2
 ----
 
 would create an entry in the resource like this:
 
 .An example OCF resource with instance attributes
 =====
 [source,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.
 
 .Displaying the metadata for the Dummy resource agent template
 =====
 ----
 # export OCF_ROOT=/usr/lib/ocf
 # $OCF_ROOT/resource.d/pacemaker/Dummy meta-data
 ----
 [source,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-{OCF_RESOURCE_INSTANCE}.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>
 -------
 =====
 
 == Resource Operations ==
 
 indexterm:[Resource,Action]
 
 Operations are actions the cluster can perform on a resource,
 such as start, stop and monitor.
 
 As an example, by default the cluster will not ensure your resources are still
 healthy.  To instruct the cluster to do this, you need to add a
 +monitor+ operation to the resource's definition.
 
 .An OCF resource with a recurring health check
 =====
 [source,XML]
 -------
 <primitive id="Public-IP" class="ocf" type="IPaddr" provider="heartbeat">
   <operations>
      <op id="public-ip-check" 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>
 -------
 =====
 
 .Properties of an Operation
 [width="95%",cols="2m,3,6<a",options="header",align="center"]
 |=========================================================
 
 |Field
 |Default
 |Description
 
 |id
 |
 |A unique name for the operation.
  indexterm:[id,Action Property]
  indexterm:[Action,Property,id]
 
 |name
 |
 |The action to perform. Common values: +monitor+, +start+, +stop+
  indexterm:[name,Action Property]
  indexterm:[Action,Property,name]
 
 |interval
 |0
 |How frequently (in seconds) to perform the operation. A value of 0 means never.
  indexterm:[interval,Action Property]
  indexterm:[Action,Property,interval]
 
 |timeout
 |
 |How long to wait before declaring the action has failed
  indexterm:[timeout,Action Property]
  indexterm:[Action,Property,timeout]
 
 |on-fail
 |restart (except for +stop+ operations, which default to fence when STONITH is enabled and block otherwise)
 |The action to take if this action ever fails. Allowed values:
 
 * +ignore:+ Pretend the resource did not fail.
 * +block:+ Don't perform any further operations on the resource.
 * +stop:+ Stop the resource and do not start it elsewhere.
 * +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.
 
 indexterm:[on-fail,Action Property]
 indexterm:[Action,Property,on-fail]
 
 |enabled
 |TRUE
 |If +false+, the operation is treated as if it does not exist. Allowed
  values: +true+, +false+
  indexterm:[enabled,Action Property]
  indexterm:[Action,Property,enabled]
 
 |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 next section).
  Allowed values: +true+, +false+.
  indexterm:[enabled,Action Property]
  indexterm:[Action,Property,enabled]
 
+|role
+|
+|This option only makes sense for recurring operations.  It restricts
+ the operation to a specific role.  The truely paranoid can even
+ specify +role=Stopped+ which allows the cluster to detect an admin
+ that manually started cluster services.
+ Allowed values: +Stopped+, +Started+, +Slave+, +Master+.
+ indexterm:[role,Action Property]
+ indexterm:[Action,Property,role]
+
 |=========================================================
 
 [[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,
 
 ----
 # 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 Resources Take a Long Time to Start/Stop ===
 
 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.
 
 .An OCF resource with custom timeouts for its implicit actions
 =====
 [source,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.
 
 .An OCF resource with two recurring health checks, performing different levels of checks specified via +OCF_CHECK_LEVEL+.
 =====
 [source,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.
 
 .Example of an OCF resource with a disabled health check
 =====
 [source,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:
 
 ----
 # 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
 ----
 # cibadmin --modify --xml-text '<op id="public-ip-check" enabled="true"/>'
 ----