Program description
Introduction to the user interface
Shadow CIB usage
Configuration templates
Resource testing
Tab completion
Configuration semantic checks
Access Control Lists (ACL)
Command reference
cib
new
delete
reset
commit
use
diff
list
import
cibstatus
ra
classes
list
meta
providers
resource
status
start
stop
restart
promote
demote
manage
unmanage
migrate
unmigrate
param
secret
meta
utilization
failcount
cleanup
refresh
reprobe
trace
untrace
node
status
show
standby
online
maintenance
ready
fence
clearstate
delete
attribute
utilization
status-attr
site
ticket
options
skill-level
user
editor
pager
sort-elements
wait
output
colorscheme
check-frequency
check-mode
add-quotes
manage-children
show
save
reset
configure
node
primitive
monitor
group
clone
ms
rsc
location
colocation
order
rsc
property
rsc
fencing
role
user
op
schema
show
edit
filter
delete
default-timeouts
rename
modgroup
refresh
erase
ptest
rsctest
cib
cibstatus
template
commit
verify
upgrade
save
load
graph
xml
template
new
load
edit
delete
list
apply
show
cibstatus
load
save
origin
show
node
op
quorum
ticket
run
simulate
history
latest
limit
source
refresh
detail
setnodes
resource
node
log
exclude
peinputs
transition
show
graph
diff
session

crm(8)

Note
We have moved! The latest version of this document can be found on http://crmsh.github.io.
Note
This is the documentation for stable release 1.2.6 of crmsh.

NAME

crm - Pacemaker command line interface for configuration and management

SYNOPSIS

crm [-D output_type] [-f file] [-c cib] [-H hist_src] [-hFRDw] [--version] [args]

DESCRIPTION

Pacemaker configuration is stored in a CIB file (Cluster Information Base). The CIB is a set of instructions coded in XML. Editing the CIB is a challenge, not only due to its complexity and a wide variety of options, but also because XML is more computer than user friendly. The crm shell alleviates this issue significantly by introducing small and simple configuration language. The CIB is translated into this language on the fly.

crm is also a management tool. For management tasks it relies almost exclusively on other command line tools, such as crm_resource(8) or crm_attribute(8). Use of these programs is, however, plagued by the notorious weakness common to all UNIX tools: a multitude of options, necessary for operation and yet very hard to remember. crm tries to present a consistent interface to the user and to hide the arcane detail.

It may be used either as an interactive shell or for single commands directly on the shell’s command line. It is also possible to feed it a set of commands from standard input or a file, thus turning it into a scripting tool. Templates with ready made configurations may help newbies learn about the cluster configuration or facilitate testing procedures.

The crm shell is line oriented: every command must start and finish on the same line. It is possible to use a continuation character (\) to write one command in two or more lines. The continuation character is commonly used when displaying configurations.

OPTIONS

-f, --file=FILE

Load commands from the given file. If the file is - then use terminal stdin.

-c, --cib=CIB

Start the session with the given shadow CIB file. Equivalent to cib use.

-D, --display=OUTPUT_TYPE

Choose one of the output options: plain, color, or uppercase. The default is color if the terminal emulation supports colors. Otherwise, plain is used.

-F, --force

Make crm proceed with doing changes even though it would normally ask user to confirm some of them. Mostly useful in scripts.

-w, --wait

Make crm wait for the cluster transition to finish (for the changes to take effect) after each processed line.

-H, --history=DIR|FILE

The history commands can examine either live cluster (default) or a report generated by hb_report. Use this option to specify a directory or file containing the report.

-h, --help

Print help page.

--version

Print crmsh version and build information (Mercurial Hg changeset hash).

-R, --regression-tests

Run in the regression test mode. Used mainly by the regression testing suite.

-d, --debug

Print some debug information. Used by developers. [Not yet refined enough to print useful information for other users.]

Introduction to the user interface

Arguably the most important aspect of crm is the user interface. We begin with an informal introduction so that the reader may get acquainted with it and get a general feeling of the tool. It is probably best just to give some examples:

  1. Command line (one-shot) use:

    # crm resource stop www_app
  2. Interactive use:

    # crm
    crm(live)# resource
    crm(live)resource# unmanage tetris_1
    crm(live)resource# end
    crm(live)# node standby node4
  3. Cluster configuration:

    # crm configure<<EOF
      #
      # resources
      #
      primitive disk0 iscsi \
        params portal=192.168.2.108:3260 target=iqn.2008-07.com.suse:disk0
      primitive fs0 Filesystem \
        params device=/dev/disk/by-label/disk0 directory=/disk0 fstype=ext3
      primitive internal_ip IPaddr params ip=192.168.1.101
      primitive apache apache \
        params configfile=/disk0/etc/apache2/site0.conf
      primitive apcfence stonith:apcsmart \
        params ttydev=/dev/ttyS0 hostlist="node1 node2" \
        op start timeout=60s
      primitive pingd pingd \
        params name=pingd dampen=5s multiplier=100 host_list="r1 r2"
      #
      # monitor apache and the UPS
      #
      monitor apache 60s:30s
      monitor apcfence 120m:60s
      #
      # cluster layout
      #
      group internal_www \
        disk0 fs0 internal_ip apache
      clone fence apcfence \
        meta globally-unique=false clone-max=2 clone-node-max=1
      clone conn pingd \
        meta globally-unique=false clone-max=2 clone-node-max=1
      location node_pref internal_www \
        rule 50: #uname eq node1 \
        rule pingd: defined pingd
      #
      # cluster properties
      #
      property stonith-enabled=true
      commit
    EOF

If you’ve ever done a CRM style configuration, you should be able to understand the above examples without much difficulties. The shell should provide a means to manage the cluster efficiently or put together a configuration in a concise manner.

The (live) string in the prompt signifies that the current CIB in use is the cluster live configuration. It is also possible to work with the so-called shadow CIBs, i.e. configurations which are stored in files and aren’t active, but may be applied at any time to the cluster.

Since the CIB is hierarchical such is the interface too. There are several levels and entering each of them enables the user to use a certain set of commands.

Shadow CIB usage

Shadow CIB is a normal cluster configuration stored in a file. They may be manipulated in the same way like the live CIB, but these changes have no effect on the cluster resources. The administrator may choose to apply any of them to the cluster, thus replacing the running configuration with the one which is in the shadow CIB. The crm prompt always contains the name of the configuration which is currently in use or string live if we are using the current cluster configuration.

At the configure level no changes take place before the commit command. Sometimes though, the administrator may start working with the running configuration, but change mind and instead of committing the changes to the cluster save them to a shadow CIB. This short configure session excerpt shows how:

    crm(live)configure# cib new test-2
    INFO: test-2 shadow CIB created
    crm(test-2)configure# commit

Configuration templates

Configuration templates are ready made configurations created by cluster experts. They are designed in such a way so that users may generate valid cluster configurations with minimum effort. If you are new to Pacemaker, templates may be the best way to start.

We will show here how to create a simple yet functional Apache configuration:

    # crm configure
    crm(live)configure# template
    crm(live)configure template# list templates
    apache       filesystem   virtual-ip
    crm(live)configure template# new web <TAB><TAB>
    apache       filesystem   virtual-ip
    crm(live)configure template# new web apache
    INFO: pulling in template apache
    INFO: pulling in template virtual-ip
    crm(live)configure template# list
    web2-d       web2         vip2         web3         vip          web

We enter the template level from configure. Use the list command to show templates available on the system. The new command creates a configuration from the apache template. You can use tab completion to pick templates. Note that the apache template depends on a virtual IP address which is automatically pulled along. The list command shows the just created web configuration, among other configurations (I hope that you, unlike me, will use more sensible and descriptive names).

The show command, which displays the resulting configuration, may be used to get an idea about the minimum required changes which have to be done. All ERROR messages show the line numbers in which the respective parameters are to be defined:

    crm(live)configure template# show
    ERROR: 23: required parameter ip not set
    ERROR: 61: required parameter id not set
    ERROR: 65: required parameter configfile not set
    crm(live)configure template# edit

The edit command invokes the preferred text editor with the web configuration. At the top of the file, the user is advised how to make changes. A good template should require from the user to specify only parameters. For example, the web configuration we created above has the following required and optional parameters (all parameter lines start with %%):

    $ grep -n ^%% ~/.crmconf/web
    23:%% ip
    31:%% netmask
    35:%% lvs_support
    61:%% id
    65:%% configfile
    71:%% options
    76:%% envfiles

These lines are the only ones that should be modified. Simply append the parameter value at the end of the line. For instance, after editing this template, the result could look like this (we used tabs instead of spaces to make the values stand out):

    $ grep -n ^%% ~/.crmconf/web
    23:%% ip                192.168.1.101
    31:%% netmask
    35:%% lvs_support
    61:%% id                websvc
    65:%% configfile        /etc/apache2/httpd.conf
    71:%% options
    76:%% envfiles

As you can see, the parameter line format is very simple:

    %% <name> <value>

After editing the file, use show again to display the configuration:

    crm(live)configure template# show
    primitive virtual-ip ocf:heartbeat:IPaddr \
            params ip="192.168.1.101"
    primitive apache ocf:heartbeat:apache \
            params configfile="/etc/apache2/httpd.conf"
    monitor apache 120s:60s
    group websvc \
            apache virtual-ip

The target resource of the apache template is a group which we named websvc in this sample session.

This configuration looks exactly as you could type it at the configure level. The point of templates is to save you some typing. It is important, however, to understand the configuration produced.

Finally, the configuration may be applied to the current crm configuration (note how the configuration changed slightly, though it is still equivalent, after being digested at the configure level):

    crm(live)configure template# apply
    crm(live)configure template# cd ..
    crm(live)configure# show
    node xen-b
    node xen-c
    primitive apache ocf:heartbeat:apache \
        params configfile="/etc/apache2/httpd.conf" \
        op monitor interval="120s" timeout="60s"
    primitive virtual-ip ocf:heartbeat:IPaddr \
        params ip="192.168.1.101"
    group websvc apache virtual-ip

Note that this still does not commit the configuration to the CIB which is used in the shell, either the running one (live) or some shadow CIB. For that you still need to execute the commit command.

To complete our example, we should also define the preferred node to run the service:

    crm(live)configure# location websvc-pref websvc 100: xen-b

If you are not happy with some resource names which are provided by default, you can rename them now:

    crm(live)configure# rename virtual-ip intranet-ip
    crm(live)configure# show
    node xen-b
    node xen-c
    primitive apache ocf:heartbeat:apache \
            params configfile="/etc/apache2/httpd.conf" \
            op monitor interval="120s" timeout="60s"
    primitive intranet-ip ocf:heartbeat:IPaddr \
            params ip="192.168.1.101"
    group websvc apache intranet-ip
    location websvc-pref websvc 100: xen-b

To summarize, working with templates typically consists of the following steps:

  • new: create a new configuration from templates

  • edit: define parameters, at least the required ones

  • show: see if the configuration is valid

  • apply: apply the configuration to the configure level

Resource testing

The amount of detail in a cluster makes all configurations prone to errors. By far the largest number of issues in a cluster is due to bad resource configuration. The shell can help quickly diagnose such problems. And considerably reduce your keyboard wear.

Let’s say that we entered the following configuration:

    node xen-b
    node xen-c
    node xen-d
    primitive fencer stonith:external/libvirt \
            params hypervisor_uri="qemu+tcp://10.2.13.1/system" \
                hostlist="xen-b xen-c xen-d" \
            op monitor interval="2h"
    primitive svc ocf:heartbeat:Xinetd \
            params service="systat" \
            op monitor interval="30s"
    primitive intranet-ip ocf:heartbeat:IPaddr2 \
            params ip="10.2.13.100" \
            op monitor interval="30s"
    primitive apache ocf:heartbeat:apache \
            params configfile="/etc/apache2/httpd.conf" \
            op monitor interval="120s" timeout="60s"
    group websvc apache intranet-ip
    location websvc-pref websvc 100: xen-b

Before typing commit to submit the configuration to the cib we can make sure that all resources are usable on all nodes:

    crm(live)configure# rsctest websvc svc fencer

It is important that resources being tested are not running on any nodes. Otherwise, the rsctest command will refuse to do anything. Of course, if the current configuration resides in a CIB shadow, then a commit is irrelevant. The point being that resources are not running on any node.

Note on stopping all resources

Alternatively to not committing a configuration, it is also possible to tell Pacemaker not to start any resources:

    crm(live)configure# property stop-all-resources="yes"

Almost none---resources of class stonith are still started. But shell is not as strict when it comes to stonith resources.

Order of resources is significant insofar that a resource depends on all resources to its left. In most configurations, it’s probably practical to test resources in several runs, based on their dependencies.

Apart from groups, crm does not interpret constraints and therefore knows nothing about resource dependencies. It also doesn’t know if a resource can run on a node at all in case of an asymmetric cluster. It is up to the user to specify a list of eligible nodes if a resource is not meant to run on every node.

Tab completion

The crm makes extensive use of tab completion. The completion is both static (i.e. for crm commands) and dynamic. The latter takes into account the current status of the cluster or information from installed resource agents. Sometimes, completion may also be used to get short help on resource parameters. Here a few examples:

    crm(live)# resource
    crm(live)resource# <TAB><TAB>
    bye           failcount     move          restart       unmigrate
    cd            help          param         show          unmove
    cleanup       list          promote       start         up
    demote        manage        quit          status utilization
    end           meta          refresh       stop
    exit          migrate       reprobe       unmanage
    crm(live)resource# end
    crm(live)# configure
    crm(live)configure# primitive fence-1 <TAB><TAB>
    heartbeat:  lsb:        ocf:        stonith:
    crm(live)configure# primitive fence-1 stonith:<TAB><TAB>
    apcmaster                external/ippower9258     fence_legacy
    apcmastersnmp            external/kdumpcheck      ibmhmc
    apcsmart                 external/libvirt         ipmilan
    baytech                  external/nut             meatware
    bladehpi                 external/rackpdu         null
    cyclades                 external/riloe           nw_rpc100s
    drac3                    external/sbd             rcd_serial
    external/drac5           external/ssh             rps10
    external/dracmc-telnet   external/ssh-bad         ssh
    external/hmchttp         external/ssh-slow        suicide
    external/ibmrsa          external/vmware          wti_mpc
    external/ibmrsa-telnet   external/xen0            wti_nps
    external/ipmi            external/xen0-ha
    crm(live)configure# primitive fence-1 stonith:ipmilan params <TAB><TAB>
    auth=      hostname=  ipaddr=    login=     password=  port=      priv=
    crm(live)configure# primitive fence-1 stonith:ipmilan params auth=<TAB><TAB>
    auth* (string)
        The authorization type of the IPMI session ("none", "straight", "md2", or "md5")
    crm(live)configure# primitive fence-1 stonith:ipmilan params auth=

Configuration semantic checks

Resource definitions may be checked against the meta-data provided with the resource agents. These checks are currently carried out:

  • are required parameters set

  • existence of defined parameters

  • timeout values for operations

The parameter checks are obvious and need no further explanation. Failures in these checks are treated as configuration errors.

The timeouts for operations should be at least as long as those recommended in the meta-data. Too short timeout values are a common mistake in cluster configurations and, even worse, they often slip through if cluster testing was not thorough. Though operation timeouts issues are treated as warnings, make sure that the timeouts are usable in your environment. Note also that the values given are just advisory minimum---your resources may require longer timeouts.

User may tune the frequency of checks and the treatment of errors by the check-frequency and check-mode preferences.

Note that if the check-frequency is set to always and the check-mode to strict, errors are not tolerated and such configuration cannot be saved.

Access Control Lists (ACL)

By default, the users from the haclient group have full access to the cluster (or, more precisely, to the CIB). Access control lists allow for finer access control to the cluster.

Access control lists consist of an ordered set of access rules. Each rule allows read or write access or denies access completely. Rules are typically combined to produce a specific role. Then, users may be assigned a role.

For instance, this is a role which defines a set of rules allowing management of a single resource:

    role bigdb_admin \
        write meta:bigdb:target-role \
        write meta:bigdb:is-managed \
        write location:bigdb \
        read ref:bigdb

The first two rules allow modifying the target-role and is-managed meta attributes which effectively enables users in this role to stop/start and manage/unmanage the resource. The constraints write access rule allows moving the resource around. Finally, the user is granted read access to the resource definition.

For proper operation of all Pacemaker programs, it is advisable to add the following role to all users:

    role read_all \
        read cib

For finer grained read access try with the rules listed in the following role:

    role basic_read \
        read node attribute:uname \
        read node attribute:type \
        read property \
        read status

It is however possible that some Pacemaker programs (e.g. ptest) may not function correctly if the whole CIB is not readable.

Some of the ACL rules in the examples above are expanded by the shell to XPath specifications. For instance, meta:bigdb:target-role is a shortcut for //primitive[@id='bigdb']/meta_attributes/nvpair[@name='target-role']. You can see the expansion by showing XML:

    crm(live) configure# show xml bigdb_admin
    ...
    <acls>
      <acl_role id="bigdb_admin">
          <write id="bigdb_admin-write"
          xpath="//primitive[@id='bigdb']/meta_attributes/nvpair[@name='target-role']"/>

Many different XPath expressions can have equal meaning. For instance, the following two are equal, but only the first one is going to be recognized as shortcut:

      //primitive[@id='bigdb']/meta_attributes/nvpair[@name='target-role']
      //resources/primitive[@id='bigdb']/meta_attributes/nvpair[@name='target-role']

XPath is a powerful language, but you should try to keep your ACL xpaths simple and the builtin shortcuts should be used whenever possible.

Command reference

We define a small and simple language. Most commands consist of just a list of simple tokens. The only complex constructs are found at the configure level.

The syntax is described in a somewhat informal manner: <> denotes a string, [] means that the construct is optional, the ellipsis (...) signifies that the previous construct may be repeated, | means pick one of many, and the rest are literals (strings, :, =).

status

Show cluster status. The status is displayed by crm_mon. Supply additional arguments for more information or different format. See crm_mon(8) for more details.

Usage:

        status [<option> ...]

        option :: bynode | inactive | ops | timing | failcounts

cib (shadow CIBs)

This level is for management of shadow CIBs. It is available both at the top level and the configure level.

All the commands are implemented using cib_shadow(8) and the CIB_shadow environment variable. The user prompt always includes the name of the currently active shadow or the live CIB.

new

Create a new shadow CIB. The live cluster configuration and status is copied to the shadow CIB. Specify withstatus if you want to edit the status section of the shadow CIB (see the cibstatus section). Add force to force overwriting the existing shadow CIB.

To start with an empty configuration that is not copied from the live CIB, specify the empty keyword. (This also allows a shadow CIB to be created in case no cluster is running.)

Usage:

        new <cib> [withstatus] [force] [empty]

delete

Delete an existing shadow CIB.

Usage:

        delete <cib>

reset

Copy the current cluster configuration into the shadow CIB.

Usage:

        reset <cib>

commit

Apply a shadow CIB to the cluster.

Usage:

        commit <cib>

use

Choose a CIB source. If you want to edit the status from the shadow CIB specify withstatus (see cibstatus). Leave out the CIB name to switch to the running CIB.

Usage:

        use [<cib>] [withstatus]

diff

Print differences between the current cluster configuration and the active shadow CIB.

Usage:

        diff

list

List existing shadow CIBs.

Usage:

        list

import

At times it may be useful to create a shadow file from the existing CIB. The CIB may be specified as file or as a PE input file number. The shell will look up files in the local directory first and then in the PE directory (typically /var/lib/pengine). Once the CIB file is found, it is copied to a shadow and this shadow is immediately available for use at both configure and cibstatus levels.

If the shadow name is omitted then the target shadow is named after the input CIB file.

Note that there are often more than one PE input file, so you may need to specify the full name.

Usage:

        import {<file>|<number>} [<shadow>]

Examples:

        import pe-warn-2222
        import 2289 issue2

cibstatus

Enter edit and manage the CIB status section level. See the CIB status management section.

ra

This level contains commands which show various information about the installed resource agents. It is available both at the top level and at the configure level.

classes

Print all resource agents' classes and, where appropriate, a list of available providers.

Usage:

        classes

list

List available resource agents for the given class. If the class is ocf, supply a provider to get agents which are available only from that provider.

Usage:

        list <class> [<provider>]

Example:

        list ocf pacemaker

meta (info)

Show the meta-data of a resource agent type. This is where users can find information on how to use a resource agent. It is also possible to get information from some programs: pengine, crmd, cib, and stonithd. Just specify the program name instead of an RA.

Usage:

        info [<class>:[<provider>:]]<type>
        info <type> <class> [<provider>] (obsolete)

Example:

        info apache
        info ocf:pacemaker:Dummy
        info stonith:ipmilan
        info pengine

providers

List providers for a resource agent type. The class parameter defaults to ocf.

Usage:

        providers <type> [<class>]

Example:

        providers apache

resource

At this level resources may be managed.

All (or almost all) commands are implemented with the CRM tools such as crm_resource(8).

status (show, list)

Print resource status. If the resource parameter is left out status of all resources is printed.

Usage:

        status [<rsc>]

start

Start a resource by setting the target-role attribute. If there are multiple meta attributes sets, the attribute is set in all of them. If the resource is a clone, all target-role attributes are removed from the children resources.

For details on group management see options manage-children.

Usage:

        start <rsc>

stop

Stop a resource using the target-role attribute. If there are multiple meta attributes sets, the attribute is set in all of them. If the resource is a clone, all target-role attributes are removed from the children resources.

For details on group management see options manage-children.

Usage:

        stop <rsc>

restart

Restart a resource. This is essentially a shortcut for resource stop followed by a start. The shell is first going to wait for the stop to finish, that is for all resources to really stop, and only then to order the start action. Due to this command entailing a whole set of operations, informational messages are printed to let the user see some progress.

For details on group management see options manage-children.

Usage:

        restart <rsc>

Example:

        # crm resource restart g_webserver
        INFO: ordering g_webserver to stop
        waiting for stop to finish .... done
        INFO: ordering g_webserver to start
        #

promote

Promote a master-slave resource using the target-role attribute.

Usage:

        promote <rsc>

demote

Demote a master-slave resource using the target-role attribute.

Usage:

        demote <rsc>

manage

Manage a resource using the is-managed attribute. If there are multiple meta attributes sets, the attribute is set in all of them. If the resource is a clone, all is-managed attributes are removed from the children resources.

For details on group management see options manage-children.

Usage:

        manage <rsc>

unmanage

Unmanage a resource using the is-managed attribute. If there are multiple meta attributes sets, the attribute is set in all of them. If the resource is a clone, all is-managed attributes are removed from the children resources.

For details on group management see options manage-children.

Usage:

        unmanage <rsc>

migrate (move)

Migrate a resource to a different node. If node is left out, the resource is migrated by creating a constraint which prevents it from running on the current node. Additionally, you may specify a lifetime for the constraint---once it expires, the location constraint will no longer be active.

Usage:

        migrate <rsc> [<node>] [<lifetime>] [force]

unmigrate (unmove)

Remove the constraint generated by the previous migrate command.

Usage:

        unmigrate <rsc>

param

Show/edit/delete a parameter of a resource.

Usage:

        param <rsc> set <param> <value>
        param <rsc> delete <param>
        param <rsc> show <param>

Example:

        param ip_0 show ip

secret

Sensitive parameters can be kept in local files rather than CIB in order to prevent accidental data exposure. Use the secret command to manage such parameters. stash and unstash move the value from the CIB and back to the CIB respectively. The set subcommand sets the parameter to the provided value. delete removes the parameter completely. show displays the value of the parameter from the local file. Use check to verify if the local file content is valid.

Usage:

        secret <rsc> set <param> <value>
        secret <rsc> stash <param>
        secret <rsc> unstash <param>
        secret <rsc> delete <param>
        secret <rsc> show <param>
        secret <rsc> check <param>

Example:

        secret fence_1 show password
        secret fence_1 stash password
        secret fence_1 set password secret_value

meta

Show/edit/delete a meta attribute of a resource. Currently, all meta attributes of a resource may be managed with other commands such as resource stop.

Usage:

        meta <rsc> set <attr> <value>
        meta <rsc> delete <attr>
        meta <rsc> show <attr>

Example:

        meta ip_0 set target-role stopped

utilization

Show/edit/delete a utilization attribute of a resource. These attributes describe hardware requirements. By setting the placement-strategy cluster property appropriately, it is possible then to distribute resources based on resource requirements and node size. See also node utilization attributes.

Usage:

        utilization <rsc> set <attr> <value>
        utilization <rsc> delete <attr>
        utilization <rsc> show <attr>

Example:

        utilization xen1 set memory 4096

failcount

Show/edit/delete the failcount of a resource.

Usage:

        failcount <rsc> set <node> <value>
        failcount <rsc> delete <node>
        failcount <rsc> show <node>

Example:

        failcount fs_0 delete node2

cleanup

Cleanup resource status. Typically done after the resource has temporarily failed. If a node is omitted, cleanup on all nodes. If there are many nodes, the command may take a while.

Usage:

        cleanup <rsc> [<node>]

refresh

Refresh CIB from the LRM status.

Usage:

        refresh [<node>]

reprobe

Probe for resources not started by the CRM.

Usage:

        reprobe [<node>]

trace

Start tracing RA for the given operation. The trace files are stored in $HA_VARLIB/trace_ra. If the operation to be traced is monitor, note that the number of trace files can grow very quickly.

Usage:

        trace <rsc> <op> [<interval>]

Example:

        trace fs start

untrace

Stop tracing RA for the given operation.

Usage:

        untrace <rsc> <op> [<interval>]

Example:

        untrace fs start

node

Node management and status commands.

status

Show nodes' status as XML. If the node parameter is omitted then all nodes are shown.

Usage:

        status [<node>]

show

Show a node definition. If the node parameter is omitted then all nodes are shown.

Usage:

        show [<node>]

standby

Set a node to standby status. The node parameter defaults to the node where the command is run. Additionally, you may specify a lifetime for the standby---if set to reboot, the node will be back online once it reboots. forever will keep the node in standby after reboot.

Usage:

        standby [<node>] [<lifetime>]

        lifetime :: reboot | forever

online

Set a node to online status. The node parameter defaults to the node where the command is run.

Usage:

        online [<node>]

maintenance

Set the node status to maintenance. This is equivalent to the cluster-wide maintenance-mode property but puts just one node into the maintenance mode. The node parameter defaults to the node where the command is run.

Usage:

        maintenance [<node>]

ready

Set the node’s maintenance status to off. The node should be now again fully operational and capable of running resource operations.

Usage:

        ready [<node>]

fence

Make CRM fence a node. This functionality depends on stonith resources capable of fencing the specified node. No such stonith resources, no fencing will happen.

Usage:

        fence <node>

clearnodestate

Resets and clears the state of the specified node. This node is afterwards assumed clean and offline. This command can be used to manually confirm that a node has been fenced (e.g., powered off).

Be careful! This can cause data corruption if you confirm that a node is down that is, in fact, not cleanly down - the cluster will proceed as if the fence had succeeded, possibly starting resources multiple times.

Usage:

        clearstate <node>

delete

Delete a node. This command will remove the node from the CIB and, in case the cluster stack is running, use the appropriate program (crm_node or hb_delnode) to remove the node from the membership.

If the node is still listed as active and a member of our partition we refuse to remove it. With the global force option (-F) we will try to delete the node anyway.

Usage:

        delete <node>

attribute

Edit node attributes. This kind of attribute should refer to relatively static properties, such as memory size.

Usage:

        attribute <node> set <attr> <value>
        attribute <node> delete <attr>
        attribute <node> show <attr>

Example:

        attribute node_1 set memory_size 4096

utilization

Edit node utilization attributes. These attributes describe hardware characteristics as integer numbers such as memory size or the number of CPUs. By setting the placement-strategy cluster property appropriately, it is possible then to distribute resources based on resource requirements and node size. See also resource utilization attributes.

Usage:

        utilization <node> set <attr> <value>
        utilization <node> delete <attr>
        utilization <node> show <attr>

Examples:

        utilization node_1 set memory 16384
        utilization node_1 show cpu

status-attr

Edit node attributes which are in the CIB status section, i.e. attributes which hold properties of a more volatile nature. One typical example is attribute generated by the pingd utility.

Usage:

        status-attr <node> set <attr> <value>
        status-attr <node> delete <attr>
        status-attr <node> show <attr>

Example:

        status-attr node_1 show pingd

site

A cluster may consist of two or more subclusters in different and distant locations. This set of commands supports such setups.

ticket

Tickets are cluster-wide attributes. They can be managed at the site where this command is executed.

It is then possible to constrain resources depending on the ticket availability (see the rsc_ticket command for more details).

Usage:

        ticket {grant|revoke|standby|activate|show|time|delete} <ticket>

Example:

        ticket grant ticket1

options

The user may set various options for the crm shell itself.

skill-level

Based on the skill-level setting, the user is allowed to use only a subset of commands. There are three levels: operator, administrator, and expert. The operator level allows only commands at the resource and node levels, but not editing or deleting resources. The administrator may do that and may also configure the cluster at the configure level and manage the shadow CIBs. The expert may do all.

Usage:

        skill-level <level>

        level :: operator | administrator | expert
Note on security

The skill-level option is advisory only. There is nothing stopping any users change their skill level (see Access Control Lists (ACL) on how to enforce access control).

user

Sufficient privileges are necessary in order to manage a cluster: programs such as crm_verify or crm_resource and, ultimately, cibadmin have to be run either as root or as the CRM owner user (typically hacluster). You don’t have to worry about that if you run crm as root. A more secure way is to run the program with your usual privileges, set this option to the appropriate user (such as hacluster), and setup the sudoers file.

Usage:

        user system-user

Example:

        user hacluster

editor

The edit command invokes an editor. Use this to specify your preferred editor program. If not set, it will default to either the value of the EDITOR environment variable or to one of the standard UNIX editors (vi,emacs,nano).

Usage:

        editor program

Example:

        editor vim

pager

The view command displays text through a pager. Use this to specify your preferred pager program. If not set, it will default to either the value of the PAGER environment variable or to one of the standard UNIX system pagers (less,more,pg).

sort-elements

crm by default sorts CIB elements. If you want them appear in the order they were created, set this option to no.

Usage:

        sort-elements {yes|no}

Example:

        sort-elements no

wait

In normal operation, crm runs a command and gets back immediately to process other commands or get input from the user. With this option set to yes it will wait for the started transition to finish. In interactive mode dots are printed to indicate progress.

Usage:

        wait {yes|no}

Example:

        wait yes

output

crm can adorn configurations in two ways: in color (similar to for instance the ls --color command) and by showing keywords in upper case. Possible values are plain, color, and uppercase. It is possible to combine the latter two in order to get an upper case xmass tree. Just set this option to color,uppercase.

colorscheme

With output set to color, a comma separated list of colors from this option are used to emphasize:

  • keywords

  • object ids

  • attribute names

  • attribute values

  • scores

  • resource references

crm can show colors only if there is curses support for python installed (usually provided by the python-curses package). The colors are whatever is available in your terminal. Use normal if you want to keep the default foreground color.

This user preference defaults to yellow,normal,cyan,red,green,magenta which is good for terminals with dark background. You may want to change the color scheme and save it in the preferences file for other color setups.

Example:

    colorscheme yellow,normal,blue,red,green,magenta

check-frequency

Semantic check of the CIB or elements modified or created may be done on every configuration change (always), when verifying (on-verify) or never. It is by default set to always. Experts may want to change the setting to on-verify.

The checks require that resource agents are present. If they are not installed at the configuration time set this preference to never.

See Configuration semantic checks for more details.

check-mode

Semantic check of the CIB or elements modified or created may be done in the strict mode or in the relaxed mode. In the former certain problems are treated as configuration errors. In the relaxed mode all are treated as warnings. The default is strict.

See Configuration semantic checks for more details.

add-quotes

The shell (as in /bin/sh) parser strips quotes from the command line. This may sometimes make it really difficult to type values which contain white space. One typical example is the configure filter command. The crm shell will supply extra quotes around arguments which contain white space. The default is yes.

Note on quotes use

Adding quotes around arguments automatically has been introduced with version 1.2.2 and it is technically a regression. Being a regression is the only reason the add-quotes option exists. If you have custom shell scripts which would break, just set the add-quotes option to no.

For instance, with adding quotes enabled, it is possible to do the following:

    # crm configure primitive d1 ocf:heartbeat:Dummy meta description="some description here"
    # crm configure filter 'sed "s/hostlist=./&node-c /"' fencing

manage-children

Some resource management commands, such as resource stop, when the target resource is a group, may not always produce desired result. Each element, group and the primitive members, can have a meta attribute and those attributes may end up with conflicting values. Consider the following construct:

    crm(live)# configure show svc fs virtual-ip
    primitive fs ocf:heartbeat:Filesystem \
            params device="/dev/drbd0" directory="/srv/nfs" fstype="ext3" \
            op monitor interval="10s" \
            meta target-role="Started"
    primitive virtual-ip ocf:heartbeat:IPaddr2 \
            params ip="10.2.13.110" iflabel="1" \
            op monitor interval="10s" \
            op start interval="0" \
            meta target-role="Started"
    group svc fs virtual-ip \
            meta target-role="Stopped"

Even though the element svc should be stopped, the group is actually running because all its members have the target-role set to Started:

    crm(live)# resource show svc
    resource svc is running on: xen-f

Hence, if the user invokes resource stop svc the intention is not clear. This preference gives the user an opportunity to better control what happens if attributes of group members have values which are in conflict with the same attribute of the group itself.

Possible values are ask (the default), always, and never. If set to always, the crm shell removes all children attributes which have values different from the parent. If set to never, all children attributes are left intact. Finally, if set to ask, the user will be asked for each member what is to be done.

show

Display all current settings.

save

Save current settings to the rc file ($HOME/.config/crm/rc). On further crm runs, the rc file is automatically read and parsed.

reset

This command resets all user options to the defaults. If used as a single-shot command, the rc file ($HOME/.config/crm/rc) is reset to the defaults too.

configure

This level enables all CIB object definition commands.

The configuration may be logically divided into four parts: nodes, resources, constraints, and (cluster) properties and attributes. Each of these commands support one or more basic CIB objects.

Nodes and attributes describing nodes are managed using the node command.

Commands for resources are:

  • primitive

  • monitor

  • group

  • clone

  • ms/master (master-slave)

In order to streamline large configurations, it is possible to define a template which can later be referenced in primitives:

  • rsc_template

In that case the primitive inherits all attributes defined in the template.

There are three types of constraints:

  • location

  • colocation

  • order

It is possible to define fencing order (stonith resource priorities):

  • fencing_topology

Finally, there are the cluster properties, resource meta attributes defaults, and operations defaults. All are just a set of attributes. These attributes are managed by the following commands:

  • property

  • rsc_defaults

  • op_defaults

In addition to the cluster configuration, the Access Control Lists (ACL) can be setup to allow access to parts of the CIB for users other than root and hacluster. The following commands manage ACL:

  • user

  • role

The changes are applied to the current CIB only on ending the configuration session or using the commit command.

Comments start with # in the first line. The comments are tied to the element which follows. If the element moves, its comments will follow.

node

The node command describes a cluster node. Nodes in the CIB are commonly created automatically by the CRM. Hence, you should not need to deal with nodes unless you also want to define node attributes. Note that it is also possible to manage node attributes at the node level.

Usage:

        node <uname>[:<type>]
          [attributes <param>=<value> [<param>=<value>...]]
          [utilization <param>=<value> [<param>=<value>...]]

        type :: normal | member | ping

Example:

        node node1
        node big_node attributes memory=64

primitive

The primitive command describes a resource. It may be referenced only once in group, clone, or master-slave objects. If it’s not referenced, then it is placed as a single resource in the CIB.

Operations may be specified in three ways. "Anonymous" as a simple list of "op" specifications. Use that if you don’t want to reference the set of operations elsewhere. That’s by far the most common way to define operations. If reusing operation sets is desired, use the "operations" keyword along with the id to give the operations set a name and the id-ref to reference another set of operations.

Operation’s attributes which are not recognized are saved as instance attributes of that operation. A typical example is OCF_CHECK_LEVEL.

For multistate resources, roles are specified as role=<role>.

A template may be defined for resources which are of the same type and which share most of the configuration. See rsc_template for more information.

Usage:

        primitive <rsc> {[<class>:[<provider>:]]<type>|@<template>}
          [params attr_list]
          [meta attr_list]
          [utilization attr_list]
          [operations id_spec]
            [op op_type [<attribute>=<value>...] ...]

        attr_list :: [$id=<id>] <attr>=<val> [<attr>=<val>...] | $id-ref=<id>
        id_spec :: $id=<id> | $id-ref=<id>
        op_type :: start | stop | monitor

Example:

        primitive apcfence stonith:apcsmart \
          params ttydev=/dev/ttyS0 hostlist="node1 node2" \
          op start timeout=60s \
          op monitor interval=30m timeout=60s

        primitive www8 apache \
          params configfile=/etc/apache/www8.conf \
          operations $id-ref=apache_ops

        primitive db0 mysql \
          params config=/etc/mysql/db0.conf \
          op monitor interval=60s \
          op monitor interval=300s OCF_CHECK_LEVEL=10

        primitive r0 ocf:linbit:drbd \
          params drbd_resource=r0 \
          op monitor role=Master interval=60s \
          op monitor role=Slave interval=300s

        primitive xen0 @vm_scheme1 \
          params xmfile=/etc/xen/vm/xen0

monitor

Monitor is by far the most common operation. It is possible to add it without editing the whole resource. Also, long primitive definitions may be a bit uncluttered. In order to make this command as concise as possible, less common operation attributes are not available. If you need them, then use the op part of the primitive command.

Usage:

        monitor <rsc>[:<role>] <interval>[:<timeout>]

Example:

        monitor apcfence 60m:60s

Note that after executing the command, the monitor operation may be shown as part of the primitive definition.

group

The group command creates a group of resources. This can be useful when resources depend on other resources and require that those resources start in order on the same node. A commmon use of resource groups is to ensure that a server and a virtual IP are located together, and that the virtual IP is started before the server.

Grouped resources are started in the order they appear in the group, and stopped in the reverse order. If a resource in the group cannot run anywhere, resources following it in the group will not start.

group can be passed the "container" meta attribute, to indicate that it is to be used to group VM resources monitored using Nagios. The resource referred to by the container attribute must be of type ocf:heartbeat:Xen, oxf:heartbeat:VirtualDomain or ocf:heartbeat:lxc.

Usage:

        group <name> <rsc> [<rsc>...]
          [meta attr_list]
          [params attr_list]

        attr_list :: [$id=<id>] <attr>=<val> [<attr>=<val>...] | $id-ref=<id>

Example:

        group internal_www disk0 fs0 internal_ip apache \
          meta target_role=stopped

        group vm-and-services vm vm-sshd meta container="vm"

clone

The clone command creates a resource clone. It may contain a single primitive resource or one group of resources.

Usage:

        clone <name> <rsc>
          [meta attr_list]
          [params attr_list]

        attr_list :: [$id=<id>] <attr>=<val> [<attr>=<val>...] | $id-ref=<id>

Example:

        clone cl_fence apc_1 \
          meta clone-node-max=1 globally-unique=false

ms (master)

The ms command creates a master/slave resource type. It may contain a single primitive resource or one group of resources.

Usage:

        ms <name> <rsc>
          [meta attr_list]
          [params attr_list]

        attr_list :: [$id=<id>] <attr>=<val> [<attr>=<val>...] | $id-ref=<id>

Example:

        ms disk1 drbd1 \
          meta notify=true globally-unique=false
Note on id-ref usage

Instance or meta attributes (‘params` and meta) may contain a reference to another set of attributes. In that case, no other attributes are allowed. Since attribute sets’ ids, though they do exist, are not shown in the crm, it is also possible to reference an object instead of an attribute set. crm will automatically replace such a reference with the right id:

    crm(live)configure# primitive a2 www-2 meta $id-ref=a1
    crm(live)configure# show a2
    primitive a2 ocf:heartbeat:apache \
        meta $id-ref="a1-meta_attributes"
        [...]

It is advisable to give meaningful names to attribute sets which are going to be referenced.

rsc_template

The rsc_template command creates a resource template. It may be referenced in primitives. It is used to reduce large configurations with many similar resources.

Usage:

        rsc_template <name> [<class>:[<provider>:]]<type>
          [params attr_list]
          [meta attr_list]
          [utilization attr_list]
          [operations id_spec]
            [op op_type [<attribute>=<value>...] ...]

        attr_list :: [$id=<id>] <attr>=<val> [<attr>=<val>...] | $id-ref=<id>
        id_spec :: $id=<id> | $id-ref=<id>
        op_type :: start | stop | monitor

Example:

        rsc_template public_vm ocf:heartbeat:Xen \
          op start timeout=300s \
          op stop timeout=300s \
          op monitor interval=30s timeout=60s \
          op migrate_from timeout=600s \
          op migrate_to timeout=600s
        primitive xen0 @public_vm \
          params xmfile=/etc/xen/xen0
        primitive xen1 @public_vm \
          params xmfile=/etc/xen/xen1

location

location defines the preference of nodes for the given resource. The location constraints consist of one or more rules which specify a score to be awarded if the rule matches.

Usage:

        location <id> <rsc> {node_pref|rules}

        node_pref :: <score>: <node>

        rules ::
          rule [id_spec] [$role=<role>] <score>: <expression>
          [rule [id_spec] [$role=<role>] <score>: <expression> ...]

        id_spec :: $id=<id> | $id-ref=<id>
        score :: <number> | <attribute> | [-]inf
        expression :: <simple_exp> [bool_op <simple_exp> ...]
        bool_op :: or | and
        simple_exp :: <attribute> [type:]<binary_op> <value>
                      | <unary_op> <attribute>
                      | date <date_expr>
        type :: string | version | number
        binary_op :: lt | gt | lte | gte | eq | ne
        unary_op :: defined | not_defined

        date_expr :: lt <end>
                     | gt <start>
                     | in_range start=<start> end=<end>
                     | in_range start=<start> <duration>
                     | date_spec <date_spec>
        duration|date_spec ::
                     hours=<value>
                     | monthdays=<value>
                     | weekdays=<value>
                     | yearsdays=<value>
                     | months=<value>
                     | weeks=<value>
                     | years=<value>
                     | weekyears=<value>
                     | moon=<value>

Examples:

        location conn_1 internal_www 100: node1

        location conn_1 internal_www \
          rule 50: #uname eq node1 \
          rule pingd: defined pingd

        location conn_2 dummy_float \
          rule -inf: not_defined pingd or pingd number:lte 0

colocation (collocation)

This constraint expresses the placement relation between two or more resources. If there are more than two resources, then the constraint is called a resource set.

The score is used to indicate the priority of the constraint. A positive score indicates that the resources should run on the same node. A negative score that they should not run on the same node. Values of positive or negative infinity indicate a mandatory constraint.

In the two resource form, the cluster will place <with-rsc> first, and then decide where to put the <rsc> resource.

Collocation resource sets have an extra attribute (sequential) to allow for sets of resources which don’t depend on each other in terms of state. The shell syntax for such sets is to put resources in parentheses.

Sets cannot be nested.

The optional ‘node-attribute` references an attribute in nodes’ instance attributes.

Usage:

        colocation <id> <score>: <rsc>[:<role>] <with-rsc>[:<role>]
          [node-attribute=<node_attr>]

        colocation <id> <score>: <rsc>[:<role>] <rsc>[:<role>] ...
          [node-attribute=<node_attr>]

Example:

        colocation never_put_apache_with_dummy -inf: apache dummy
        colocation c1 inf: A ( B C )

order

This constraint expresses the order of actions on two resources or more resources. If there are more than two resources, then the constraint is called a resource set.

Ordered resource sets have an extra attribute to allow for sets of resources whose actions may run in parallel. The shell syntax for such sets is to put resources in parentheses.

If the subsequent resource can start or promote after any one of the resources in a set has done, enclose the set in brackets ([ and ]).

Sets cannot be nested.

Three strings are reserved to specify a kind of order constraint: Mandatory, Optional, and Serialize. It is preferred to use one of these settings instead of score. Previous versions mapped scores 0 and inf to keywords advisory and mandatory. That is still valid but deprecated.

Note on resource sets' XML attributes

The XML attribute require-all controls whether all resources in a set are, well, required. The bracketed sets actually have this attribute as well as sequential set to false. If you need a different combination, for whatever reason, just set one of the attributes within the set. Something like this:

    crm(live)configure# order o1 Mandatory: [ A B sequential=true ] C

It is up to you to find out whether such a combination makes sense.

Usage:

        order <id> {kind|<score>}: <rsc>[:<action>] <rsc>[:<action>] ...
          [symmetrical=<bool>]

        kind :: Mandatory | Optional | Serialize

Example:

        order c_apache_1 Mandatory: apache:start ip_1
        order o1 Serialize: A ( B C )
        order order_2 Mandatory: [ A B ] C

rsc_ticket

This constraint expresses dependency of resources on cluster-wide attributes, also known as tickets. Tickets are mainly used in geo-clusters, which consist of multiple sites. A ticket may be granted to a site, thus allowing resources to run there.

The loss-policy attribute specifies what happens to the resource (or resources) if the ticket is revoked. The default is either stop or demote depending on whether a resource is multi-state.

See also the site set of commands.

Usage:

        rsc_ticket <id> <ticket_id>: <rsc>[:<role>] [<rsc>[:<role>] ...]
          [loss-policy=<loss_policy_action>]

        loss_policy_action :: stop | demote | fence | freeze

Example:

        rsc_ticket ticket-A_public-ip ticket-A: public-ip
        rsc_ticket ticket-A_bigdb ticket-A: bigdb loss-policy=fence
        rsc_ticket ticket-B_storage ticket-B: drbd-a:Master drbd-b:Master

property

Set the cluster (crm_config) options.

Usage:

        property [$id=<set_id>] <option>=<value> [<option>=<value> ...]

Example:

        property stonith-enabled=true

rsc_defaults

Set defaults for the resource meta attributes.

Usage:

        rsc_defaults [$id=<set_id>] <option>=<value> [<option>=<value> ...]

Example:

        rsc_defaults failure-timeout=3m

fencing_topology

If multiple fencing (stonith) devices are available capable of fencing a node, their order may be specified by fencing_topology. The order is specified per node.

Stonith resources can be separated by , in which case all of them need to succeed. If they fail, the next stonith resource (or set of resources) is used. In other words, use comma to separate resources which all need to succeed and whitespace for serial order. It is not allowed to use whitespace around comma.

If the node is left out, the order is used for all nodes. That should reduce the configuration size in some stonith setups.

Usage:

        fencing_topology stonith_resources [stonith_resources ...]
        fencing_topology fencing_order [fencing_order ...]

        fencing_order :: <node>: stonith_resources [stonith_resources ...]

        stonith_resources :: <rsc>[,<rsc>...]

Example:

        fencing_topology poison-pill power
        fencing_topology \
            node-a: poison-pill power
            node-b: ipmi serial

role

An ACL role is a set of rules which describe access rights to CIB. Rules consist of an access right read, write, or deny and a specification denoting part of the configuration to which the access right applies. The specification can be an XPath or a combination of tag and id references. If an attribute is appended, then the specification applies only to that attribute of the matching element.

There is a number of shortcuts for XPath specifications. The meta, params, and utilization shortcuts reference resource meta attributes, parameters, and utilization respectively. The location may be used to specify location constraints most of the time to allow resource move and unmove commands. The property references cluster properties. The node allows reading node attributes. nodeattr and nodeutil reference node attributes and node capacity (utilization). The status shortcut references the whole status section of the CIB. Read access to status is necessary for various monitoring tools such as crm_mon(8) (aka crm status).

Usage:

        role <role-id> rule [rule ...]

        rule :: acl-right cib-spec [attribute:<attribute>]

        acl-right :: read | write | deny

        cib-spec :: xpath-spec | tag-ref-spec
        xpath-spec :: xpath:<xpath> | shortcut
        tag-ref-spec :: tag:<tag> | ref:<id> | tag:<tag> ref:<id>

        shortcut :: meta:<rsc>[:<attr>]
                    params:<rsc>[:<attr>]
                    utilization:<rsc>
                    location:<rsc>
                    property[:<attr>]
                    node[:<node>]
                    nodeattr[:<attr>]
                    nodeutil[:<node>]
                    status

Example:

        role app1_admin \
            write meta:app1:target-role \
            write meta:app1:is-managed \
            write location:app1 \
            read ref:app1

user

Users which normally cannot view or manage cluster configuration can be allowed access to parts of the CIB. The access is defined by a set of read, write, and deny rules as in role definitions or by referencing roles. The latter is considered best practice.

Usage:

        user <uid> {roles|rules}

        roles :: role:<role-ref> [role:<role-ref> ...]
        rules :: rule [rule ...]

Example:

        user joe \
            role:app1_admin \
            role:read_all

op_defaults

Set defaults for the operations meta attributes.

Usage:

        op_defaults [$id=<set_id>] <option>=<value> [<option>=<value> ...]

Example:

        op_defaults record-pending=true

schema

CIB’s content is validated by a RNG schema. Pacemaker supports several, depending on version. Currently supported schemas are pacemaker-1.0, pacemaker-1.1, and pacemaker-1.2.

Use this command to display or switch to another RNG schema.

Usage:

        schema [<schema>]

Example:

        schema pacemaker-1.1

show

The show command displays objects. It may display all objects or a set of objects. The user may also choose to see only objects which were changed. Optionally, the XML code may be displayed instead of the CLI representation.

Usage:

        show [xml] [<id> ...]
        show [xml] changed

edit

This command invokes the editor with the object description. As with the show command, the user may choose to edit all objects or a set of objects.

If the user insists, he or she may edit the XML edition of the object. If you do that, don’t modify any id attributes.

Usage:

        edit [xml] [<id> ...]
        edit [xml] changed
Note on renaming element ids

The edit command sometimes cannot properly handle modifying element ids. In particular for elements which belong to group or ms resources. Group and ms resources themselves also cannot be renamed. Please use the rename command instead.

filter

This command filters the given CIB elements through an external program. The program should accept input on stdin and send output to stdout (the standard UNIX filter conventions). As with the show command, the user may choose to filter all or just a subset of elements.

It is possible to filter the XML representation of objects, but probably not as useful as the configuration language. The presentation is somewhat different from what would be displayed by the show command---each element is shown on a single line, i.e. there are no backslashes and no other embelishments.

Don’t forget to put quotes around the filter if it contains spaces.

Usage:

        filter <prog> [xml] [<id> ...]
        filter <prog> [xml] changed

Examples:

        filter "sed '/^primitive/s/target-role=[^ ]*//'"
        # crm configure filter "sed '/^primitive/s/target-role=[^ ]*//'"

delete

Delete one or more objects. If an object to be deleted belongs to a container object, such as a group, and it is the only resource in that container, then the container is deleted as well. Any related constraints are removed as well.

Usage:

        delete <id> [<id>...]

default-timeouts

This command takes the timeouts from the actions section of the resource agent meta-data and sets them for the operations of the primitive.

Usage:

        default-timeouts <id> [<id>...]
Note on default-timeouts

You may be happy using this, but your applications may not. And it will tell you so at the worst possible moment. You have been warned.

rename

Rename an object. It is recommended to use this command to rename a resource, because it will take care of updating all related constraints and a parent resource. Changing ids with the edit command won’t have the same effect.

If you want to rename a resource, it must be in the stopped state.

Usage:

        rename <old_id> <new_id>

modgroup

Add or remove primitives in a group. The add subcommand appends the new group member by default. Should it go elsewhere, there are after and before clauses.

Usage:

        modgroup <id> add <id> [after <id>|before <id>]
        modgroup <id> remove <id>

Examples:

        modgroup share1 add storage2 before share1-fs

refresh

Refresh the internal structures from the CIB. All changes made during this session are lost.

Usage:

        refresh

erase

The erase clears all configuration. Apart from nodes. To remove nodes, you have to specify an additional keyword nodes.

Note that removing nodes from the live cluster may have some strange/interesting/unwelcome effects.

Usage:

        erase [nodes]

ptest (simulate)

Show PE (Policy Engine) motions using ptest(8) or crm_simulate(8).

A CIB is constructed using the current user edited configuration and the status from the running CIB. The resulting CIB is run through ptest (or crm_simulate) to show changes which would happen if the configuration is committed.

The status section may be loaded from another source and modified using the cibstatus level commands. In that case, the ptest command will issue a message informing the user that the Policy Engine graph is not calculated based on the current status section and therefore won’t show what would happen to the running but some imaginary cluster.

If you have graphviz installed and X11 session, dotty(1) is run to display the changes graphically.

Add a string of v characters to increase verbosity. ptest can also show allocation scores. utilization turns on information about the remaining capacity of nodes. With the actions option, ptest will print all resource actions.

The ptest program has been replaced by crm_simulate in newer Pacemaker versions. In some installations both could be installed. Use simulate to enfore using crm_simulate.

Usage:

        ptest [nograph] [v...] [scores] [actions] [utilization]

Examples:

        ptest scores
        ptest vvvvv
        simulate actions

rsctest

Test resources with current resource configuration. If no nodes are specified, tests are run on all known nodes.

The order of resources is significant: it is assumed that later resources depend on earlier ones.

If a resource is multi-state, it is assumed that the role on which later resources depend is master.

Tests are run sequentially to prevent running the same resource on two or more nodes. Tests are carried out only if none of the specified nodes currently run any of the specified resources. However, it won’t verify whether resources run on the other nodes.

Superuser privileges are obviously required: either run this as root or setup the sudoers file appropriately.

Note that resource testing may take some time.

Usage:

        rsctest <rsc_id> [<rsc_id> ...] [<node_id> ...]

Examples:

        rsctest my_ip websvc
        rsctest websvc nodeB

cib (shadow CIBs)

This level is for management of shadow CIBs. It is available at the configure level to enable saving intermediate changes to a shadow CIB instead of to the live cluster. This short excerpt shows how:

    crm(live)configure# cib new test-2
    INFO: test-2 shadow CIB created
    crm(test-2)configure# commit

Note how the current CIB in the prompt changed from live to test-2 after issuing the cib new command. See also the CIB shadow management for more information.

cibstatus

Enter edit and manage the CIB status section level. See the CIB status management section.

template

The specified template is loaded into the editor. It’s up to the user to make a good CRM configuration out of it. See also the template section.

Usage:

        template [xml] url

Example:

        template two-apaches.txt

commit

Commit the current configuration to the CIB in use. As noted elsewhere, commands in a configure session don’t have immediate effect on the CIB. All changes are applied at one point in time, either using commit or when the user leaves the configure level. In case the CIB in use changed in the meantime, presumably by somebody else, the crm shell will refuse to apply the changes. If you know that it’s fine to still apply them add force.

Usage:

        commit [force]

verify

Verify the contents of the CIB which would be committed.

Usage:

        verify

upgrade

If you get the CIB not supported error, which typically means that the current CIB version is coming from the older release, you may try to upgrade it to the latest revision. The command to perform the upgrade is:

    # cibadmin --upgrade --force

If we don’t recognize the current CIB as the old one, but you’re sure that it is, you may force the command.

Usage:

        upgrade [force]

save

Save the current configuration to a file. Optionally, as XML. Use - instead of file name to write the output to stdout.

Usage:

        save [xml] <file>

Example:

        save myfirstcib.txt

load

Load a part of configuration (or all of it) from a local file or a network URL. The replace method replaces the current configuration with the one from the source. The update tries to import the contents into the current configuration. The file may be a CLI file or an XML file.

Usage:

        load [xml] <method> URL

        method :: replace | update

Example:

        load xml update myfirstcib.xml
        load xml replace http://storage.big.com/cibs/bigcib.xml

graph

Create a graphviz graphical layout from the current cluster configuration.

Currently, only dot (directed graph) is supported. It is essentially a visualization of resource ordering.

The graph may be saved to a file which can be used as source for various graphviz tools (by default it is displayed in the user’s X11 session). Optionally, by specifying the format, one can also produce an image instead.

For more or different graphviz attributes, it is possible to save the default set of attributes to an ini file. If this file exists it will always override the builtin settings. The exportsettings subcommand also prints the location of the ini file.

Usage:

        graph [<gtype> [<file> [<img_format>]]]
        graph exportsettings

        gtype :: dot
        img_format :: `dot` output format (see the `-T` option)

Example:

        graph dot
        graph dot clu1.conf.dot
        graph dot clu1.conf.svg svg

xml

Even though we promissed no xml, it may happen, but hopefully very very seldom, that an element from the CIB cannot be rendered in the configuration language. In that case, the element will be shown as raw xml, prefixed by this command. That element can then be edited like any other. If the shell finds out that after the change it can digest it, then it is going to be converted into the normal configuration language. Otherwise, there is no need to use xml for configuration.

Usage:

        xml <xml>

template

User may be assisted in the cluster configuration by templates prepared in advance. Templates consist of a typical ready configuration which may be edited to suit particular user needs.

This command enters a template level where additional commands for configuration/template management are available.

new

Create a new configuration from one or more templates. Note that configurations and templates are kept in different places, so it is possible to have a configuration name equal a template name.

If you already know which parameters are required, you can set them directly on the command line.

The parameter name id is set by default to the name of the configuration.

Usage:

        new <config> <template> [<template> ...] [params name=value ...]"

Examples:

        new vip virtual-ip
        new bigfs ocfs2 params device=/dev/sdx8 directory=/bigfs

load

Load an existing configuration. Further edit, show, and apply commands will refer to this configuration.

Usage:

        load <config>

edit

Edit current or given configuration using your favourite editor.

Usage:

        edit [<config>]

delete

Remove a configuration. The loaded (active) configuration may be removed by force.

Usage:

        delete <config> [force]

list

List existing configurations or templates.

Usage:

        list [templates]

apply

Copy the current or given configuration to the current CIB. By default, the CIB is replaced, unless the method is set to "update".

Usage:

        apply [<method>] [<config>]

        method :: replace | update

show

Process the current or given configuration and display the result.

Usage:

        show [<config>]

cibstatus

The status section of the CIB keeps the current status of nodes and resources. It is modified only on events, i.e. when some resource operation is run or node status changes. For obvious reasons, the CRM has no user interface with which it is possible to affect the status section. From the user’s point of view, the status section is essentially a read-only part of the CIB. The current status is never even written to disk, though it is available in the PE (Policy Engine) input files which represent the history of cluster motions. The current status may be read using the cibadmin -Q command.

It may sometimes be of interest to see how status changes would affect the Policy Engine. The set of ‘cibstatus` level commands allow the user to load status sections from various sources and then insert or modify resource operations or change nodes’ state.

The effect of those changes may then be observed by running the ptest command at the configure level or simulate and run commands at this level. The ptest runs with the user edited CIB whereas the latter two commands run with the CIB which was loaded along with the status section.

The simulate and run commands as well as all status modification commands are implemented using crm_simulate(8).

load

Load a status section from a file, a shadow CIB, or the running cluster. By default, the current (live) status section is modified. Note that if the live status section is modified it is not going to be updated if the cluster status changes, because that would overwrite the user changes. To make crm drop changes and resume use of the running cluster status, run load live.

All CIB shadow configurations contain the status section which is a snapshot of the status section taken at the time the shadow was created. Obviously, this status section doesn’t have much to do with the running cluster status, unless the shadow CIB has just been created. Therefore, the ptest command by default uses the running cluster status section.

Usage:

        load {<file>|shadow:<cib>|live}

Example:

        load bug-12299.xml
        load shadow:test1

save

The current internal status section with whatever modifications were performed can be saved to a file or shadow CIB.

If the file exists and contains a complete CIB, only the status section is going to be replaced and the rest of the CIB will remain intact. Otherwise, the current user edited configuration is saved along with the status section.

Note that all modifications are saved in the source file as soon as they are run.

Usage:

        save [<file>|shadow:<cib>]

Example:

        save bug-12299.xml

origin

Show the origin of the status section currently in use. This essentially shows the latest load argument.

Usage:

        origin

show

Show the current status section in the XML format. Brace yourself for some unreadable output. Add changed option to get a human readable output of all changes.

Usage:

        show [changed]

node

Change the node status. It is possible to throw a node out of the cluster, make it a member, or set its state to unclean.

online

Set the node_state crmd attribute to online and the expected and join attributes to member. The effect is that the node becomes a cluster member.

offline

Set the node_state crmd attribute to offline and the expected attribute to empty. This makes the node cleanly removed from the cluster.

unclean

Set the node_state crmd attribute to offline and the expected attribute to member. In this case the node has unexpectedly disappeared.

Usage:

        node <node> {online|offline|unclean}

Example:

        node xen-b unclean

op

Edit the outcome of a resource operation. This way you can tell CRM that it ran an operation and that the resource agent returned certain exit code. It is also possible to change the operation’s status. In case the operation status is set to something other than done, the exit code is effectively ignored.

Usage:

        op <operation> <resource> <exit_code> [<op_status>] [<node>]

        operation :: probe | monitor[:<n>] | start | stop |
           promote | demote | notify | migrate_to | migrate_from
        exit_code :: <rc> | success | generic | args |
           unimplemented | perm | installed | configured | not_running |
           master | failed_master
        op_status :: pending | done | cancelled | timeout | notsupported | error

        n :: the monitor interval in seconds; if omitted, the first
           recurring operation is referenced
        rc :: numeric exit code in range 0..9

Example:

        op start d1 xen-b generic
        op start d1 xen-b 1
        op monitor d1 xen-b not_running
        op stop d1 xen-b 0 timeout

quorum

Set the quorum value.

Usage:

        quorum <bool>

Example:

        quorum false

ticket

Modify the ticket status. Tickets can be granted and revoked. Granted tickets could be activated or put in standby.

Usage:

        ticket <ticket> {grant|revoke|activate|standby}

Example:

        ticket ticketA grant

run

Run the policy engine with the edited status section.

Add a string of v characters to increase verbosity. Specify scores to see allocation scores also. utilization turns on information about the remaining capacity of nodes.

If you have graphviz installed and X11 session, dotty(1) is run to display the changes graphically.

Usage:

        run [nograph] [v...] [scores] [utilization]

Example:

        run

simulate

Run the policy engine with the edited status section and simulate the transition.

Add a string of v characters to increase verbosity. Specify scores to see allocation scores also. utilization turns on information about the remaining capacity of nodes.

If you have graphviz installed and X11 session, dotty(1) is run to display the changes graphically.

Usage:

        simulate [nograph] [v...] [scores] [utilization]

Example:

        simulate

history

Examining Pacemaker’s history is a particularly involved task. The number of subsystems to be considered, the complexity of the configuration, and the set of various information sources, most of which are not exactly human readable, keep analyzing resource or node problems accessible to only the most knowledgeable. Or, depending on the point of view, to the most persistent. The following set of commands has been devised in hope to make cluster history more accessible.

Of course, looking at all history could be time consuming regardless of how good tools at hand are. Therefore, one should first say which period he or she wants to analyze. If not otherwise specified, the last hour is considered. Logs and other relevant information is collected using hb_report. Since this process takes some time and we always need fresh logs, information is refreshed in a much faster way using pssh(1). If python-pssh is not found on the system, examining live cluster is still possible though not as comfortable.

Apart from examining live cluster, events may be retrieved from a report generated by hb_report (see also the -H option). In that case we assume that the period stretching the whole report needs to be investigated. Of course, it is still possible to further reduce the time range.

If you think you may have found a bug or just need clarification from developers or your support, the session pack command can help create a report. This is an example:

    crm(live)history# timeframe "Jul 18 12:00" "Jul 18 12:30"
    crm(live)history# session save strange_restart
    crm(live)history# session pack
    Report saved in .../strange_restart.tar.bz2
    crm(live)history#

In order to reduce report size and allow developers to concentrate on the issue, you should beforehand limit the time frame. Giving a meaningful session name helps too.

info

The info command shows most important information about the cluster.

Usage:

        info

Example:

        info

latest

The latest command shows a bit of recent history, more precisely whatever happened since the last cluster change (the latest transition). If the transition is running, the shell will first wait until it finishes.

Usage:

        latest

Example:

        latest

limit (timeframe)

All history commands look at events within certain period. It defaults to the last hour for the live cluster source. There is no limit for the hb_report source. Use this command to set the timeframe.

The time period is parsed by the dateutil python module. It covers wide range of date formats. For instance:

  • 3:00 (today at 3am)

  • 15:00 (today at 3pm)

  • 2010/9/1 2pm (September 1st 2010 at 2pm)

We won’t bother to give definition of the time specification in usage below. Either use common sense or read the dateutil documentation.

If dateutil is not available, then the time is parsed using strptime and only the kind as printed by date(1) is allowed:

  • Tue Sep 15 20:46:27 CEST 2010

Usage:

        limit [<from_time> [<to_time>]]

Examples:

        limit 10:15
        limit 15h22m 16h
        limit "Sun 5 20:46" "Sun 5 22:00"

source

Events to be examined can come from the current cluster or from a hb_report report. This command sets the source. source live sets source to the running cluster and system logs. If no source is specified, the current source information is printed.

In case a report source is specified as a file reference, the file is going to be unpacked in place where it resides. This directory is not removed on exit.

Usage:

        source [<dir>|<file>|live]

Examples:

        source live
        source /tmp/customer_case_22.tar.bz2
        source /tmp/customer_case_22
        source

refresh

This command makes sense only for the live source and makes crm collect the latest logs and other relevant information from the logs. If you want to make a completely new report, specify force.

Usage:

        refresh [force]

detail

How much detail to show from the logs.

Usage:

        detail <detail_level>

        detail_level :: small integer (defaults to 0)

Example:

        detail 1

setnodes

In case the host this program runs on is not part of the cluster, it is necessary to set the list of nodes.

Usage:

        setnodes node <node> [<node> ...]

Example:

        setnodes node_a node_b

resource

Show actions and any failures that happened on all specified resources on all nodes. Normally, one gives resource names as arguments, but it is also possible to use extended regular expressions. Note that neither groups nor clones or master/slave names are ever logged. The resource command is going to expand all of these appropriately, so that clone instances or resources which are part of a group are shown.

Usage:

        resource <rsc> [<rsc> ...]

Example:

        resource bigdb public_ip
        resource my_.*_db2
        resource ping_clone

node

Show important events that happened on a node. Important events are node lost and join, standby and online, and fence. Use either node names or extended regular expressions.

Usage:

        node <node> [<node> ...]

Example:

        node node1

log

Show messages logged on one or more nodes. Leaving out a node name produces combined logs of all nodes. Messages are sorted by time and, if the terminal emulations supports it, displayed in different colours depending on the node to allow for easier reading.

The sorting key is the timestamp as written by syslog which normally has the maximum resolution of one second. Obviously, messages generated by events which share the same timestamp may not be sorted in the same way as they happened. Such close events may actually happen fairly often.

Usage:

        log [<node>]

Example:

        log node-a

exclude

If a log is infested with irrelevant messages, those messages may be excluded by specifying a regular expression. The regular expressions used are Python extended. This command is additive. To drop all regular expressions, use exclude clear. Run exclude only to see the current list of regular expressions. Excludes are saved along with the history sessions.

Usage:

        exclude [<regex>|clear]

Example:

        exclude kernel.*ocfs2

peinputs

Every event in the cluster results in generating one or more Policy Engine (PE) files. These files describe future motions of resources. The files are listed as full paths in the current report directory. Add v to also see the creation time stamps.

Usage:

        peinputs [{<range>|<number>} ...] [v]

        range :: <n1>:<n2>

Example:

        peinputs
        peinputs 440:444 446
        peinputs v

transition

This command will print actions planned by the PE and run graphviz (dotty) to display a graphical representation of the transition. Of course, for the latter an X11 session is required. This command invokes ptest(8) in background.

The showdot subcommand runs graphviz (dotty) to display a graphical representation of the .dot file which has been included in the report. Essentially, it shows the calculation produced by pengine which is installed on the node where the report was produced. In optimal case this output should not differ from the one produced by the locally installed pengine.

The log subcommand shows the full log for the duration of the transition.

A transition can also be saved to a CIB shadow for further analysis or use with cib or configure commands (use the save subcommand). The shadow file name defaults to the name of the PE input file.

If the PE input file number is not provided, it defaults to the last one, i.e. the last transition. The last transition can also be referenced with number 0. If the number is negative, then the corresponding transition relative to the last one is chosen.

If there are warning and error PE input files or different nodes were the DC in the observed timeframe, it may happen that PE input file numbers collide. In that case provide some unique part of the path to the file.

After the ptest output, logs about events that happened during the transition are printed.

Usage:

        transition [<number>|<index>|<file>] [nograph] [v...] [scores] [actions] [utilization]
        transition showdot [<number>|<index>|<file>]
        transition log [<number>|<index>|<file>]
        transition save [<number>|<index>|<file> [name]]

Examples:

        transition
        transition 444
        transition -1
        transition pe-error-3.bz2
        transition node-a/pengine/pe-input-2.bz2
        transition showdot 444
        transition log
        transition save 0 enigma-22

show

Every transition is saved as a PE file. Use this command to render that PE file either as configuration or status. The configuration output is the same as crm configure show.

Usage:

        show <pe> [status]

        pe :: <number>|<index>|<file>|live

Examples:

        show 2066
        show pe-input-2080.bz2 status

graph

Create a graphviz graphical layout from the PE file (the transition). Every transition contains the cluster configuration which was active at the time. See also generate a directed graph from configuration.

Usage:

        graph <pe> [<gtype> [<file> [<img_format>]]]

        gtype :: dot
        img_format :: `dot` output format (see the `-T` option)

Example:

        graph -1
        graph 322 dot clu1.conf.dot
        graph 322 dot clu1.conf.svg svg

diff

A transition represents a change in cluster configuration or state. Use diff to see what has changed between two transitions.

If you want to specify the current cluster configuration and status, use the string live.

Normally, the first transition specified should be the one which is older, but we are not going to enforce that.

Note that a single configuration update may result in more than one transition.

Usage:

        diff <pe> <pe> [status] [html]

        pe :: <number>|<index>|<file>|live

Examples:

        diff 2066 2067
        diff pe-input-2080.bz2 live status

session

Sometimes you may want to get back to examining a particular history period or bug report. In order to make that easier, the current settings can be saved and later retrieved.

If the current history being examined is coming from a live cluster the logs, PE inputs, and other files are saved too, because they may disappear from nodes. For the existing reports coming from hb_report, only the directory location is saved (not to waste space).

A history session may also be packed into a tarball which can then be sent to support.

Leave out subcommand to see the current session.

Usage:

        session [{save|load|delete} <name> | pack [<name>] | update | list]

Examples:

        session save bnc966622
        session load rsclost-2
        session list

end (cd, up)

The end command ends the current level and the user moves to the parent level. This command is available everywhere.

Usage:

        end

help

The help command prints help for the current level or for the specified topic (command). This command is available everywhere.

Usage:

        help [<topic>]

quit (exit, bye)

Leave the program.

BUGS

Even though all sensible configurations (and most of those that are not) are going to be supported by the crm shell, I suspect that it may still happen that certain XML constructs may confuse the tool. When that happens, please file a bug report.

The crm shell will not try to update the objects it does not understand. Of course, it is always possible to edit such objects in the XML format.

AUTHOR

Dejan Muhamedagic, <dejan@suse.de> and many OTHERS

SEE ALSO

crm_resource(8), crm_attribute(8), crm_mon(8), cib_shadow(8), ptest(8), dotty(1), crm_simulate(8), cibadmin(8)

COPYING

Copyright (C) 2008-2011 Dejan Muhamedagic. Free use of this software is granted under the terms of the GNU General Public License (GPL).